Metal compartmentation and speciation in a soil sentinel: the earthworm, Dendrodrilus rubidus.

Earthworms are well-studied organisms in ecotoxicology because of their keystone ecological status and metal-accumulating capacity. However, the direct estimation of the bioreactive fractions of accumulated metal burdens remains technically elusive. In this study we exploited two physical techniques, electron probe X-ray microanalysis (EPXMA) and X-ray absorption spectroscopy (XAS), to improve understanding of the subcellular spatial distributions, ligand affinities, and coordination chemistries of Cd, Pb and Zn in a field population of the epigeic earthworm, Dendrodrilus rubidus. EPXMA and XAS analyses were performed on cryopreparations to maintain compositional fidelity; EPXMA data were analyzed by multivariate statistics. XAS provided whole-worm insights; EPXMA provided in situ, subcellular data from the major metal-sequestering tissue, the chloragog. Both techniques showed that Cd is coordinated with S; the measured Cd-S bond distance in XAS suggests a metallothionein-type ligand. The mean Cd:S molar ratio (EPXMA) of 0.36 is higher than the ratio of 0.29 estimated from published biochemical data. EPXMA and XAS data also found that Ca, Pb, and Zn are predominantly bound to one or more O-donating, probably phosphate-rich, ligands. X-ray distribution maps (EPXMA) of the hepatocyte-resembling chloragocytes revealed that the O-seeking (Ca, Pb, Zn) metals and S-seeking Cd bioaccumulate in distinct organelles. Extended X-ray absorption fine structure showed that the Pb complex is not biogenic pyromorphite, although X-ray absorption near edge structure did not eliminate the possibility. XAS provided no evidence of Pb spillage from the "sequestration compartment" within D. rubidus. However, the correspondence of Pb with Ca and P in EPXMA is not as strong as that of Zn. This is indicative either of spillover or of a second, hitherto unidentified, sequestered-Pb pool. By exploiting the complimentary techniques of EPXMA and XAS,we are closer to describing the mechanistic link between equilibrated body burdens and biomarker responses in earthworms.

Arsenic-speciation in arsenate-resistant and non-resistant populations of the earthworm, Lumbricus rubellus.

Arsenic speciation was determined in Lumbricus rubellus Hoffmeister from arsenic-contaminated mine spoil sites and an uncontaminated site using HPLC-MS, HPLC-ICP-MS and XAS. It was previously demonstrated that L. rubellus from mine soils were more arsenate resistant than from the uncontaminated site and we wished to investigate if arsenic speciation had a role in this resistance. Earthworms from contaminated sites had considerably higher arsenic body burdens (maximum 1,358 mg As kg-1) compared to the uncontaminated site (maximum 13 mg As kg-1). The only organo-arsenic species found in methanol/water extracts for all earthworm populations was arsenobetaine, quantified using both HPLC-MS and HPLC-ICP-MS. Arsenobetaine concentrations were high in L. rubellus from the uncontaminated site when concentrations were expressed as a percentage of the total arsenic burden (23% mean), but earthworms from the contaminated sites with relatively low arsenic burdens also had these high levels of arsenobetaine (17% mean). As arsenic body burden increased, the percentage of arsenobetaine present decreased in a dose dependent manner, although its absolute concentration rose with increasing arsenic burden. The origin of this arsenobetaine is discussed. XAS analysis of arsenic mine L. rubellus showed that arsenic was primarily present as As(III) co-ordinated with sulfur (30% approx.), with some As(v) with oxygen (5%). Spectra for As(III) complexed with glutathione gave a very good fit to the spectra obtained for the earthworms, suggesting a role for sulfur co-ordination in arsenic metabolism at higher earthworm arsenic burdens. It is also possible that the disintegration of As(III)-S complexes may have taken place due to (a) processing of the sample, (b) storage of the extract or (c) HPLC anion exchange. HPLC-ICP-MS analysis of methanol extracts showed the presence of arsenite and arsenate, suggesting that these sulfur complexes disintegrate on extraction. The role of arsenic speciation in the resistance of L. rubellus to arsenate is considered.

Arsenic accumulation and metabolism in rice (Oryza sativa L.).

The use of arsenic (As) contaminated groundwater for irrigation of crops has resulted in elevated concentrations of arsenic in agricultural soils in Bangladesh, West Bengal (India), and elsewhere. Paddy rice (Oryza sativa L.) is the main agricultural crop grown in the arsenic-affected areas of Bangladesh. There is, therefore, concern regarding accumulation of arsenic in rice grown those soils. A greenhouse study was conducted to examine the effects of arsenic-contaminated irrigation water on the growth of rice and uptake and speciation of arsenic. Treatments of the greenhouse experiment consisted of two phosphate doses and seven different arsenate concentrations ranging from 0 to 8 mg of As L(-1) applied regularly throughout the 170-day post-transplantation growing period until plants were ready for harvesting. Increasing the concentration of arsenate in irrigation water significantly decreased plant height, grain yield, the number of filled grains, grain weight, and root biomass, while the arsenic concentrations in root, straw, and rice husk increased significantly. Concentrations of arsenic in rice grain did not exceed the food hygiene concentration limit (1.0 mg of As kg(-1) dry weight). The concentrations of arsenic in rice straw (up to 91.8 mg kg(-1) for the highest As treatment) were of the same order of magnitude as root arsenic concentrations (up to 107.5 mg kg(-1)), suggesting that arsenic can be readily translocated to the shoot. While not covered by food hygiene regulations, rice straw is used as cattle feed in many countries including Bangladesh. The high arsenic concentrations may have the potential for adverse health effects on the cattle and an increase of arsenic exposure in humans via the plant-animal-human pathway. Arsenic concentrations in rice plant parts except husk were not affected by application of phosphate. As the concentration of arsenic in the rice grain was low, arsenic speciation was performed only on rice straw to predict the risk associated with feeding contaminated straw to the cattle. Speciation of arsenic in tissues (using HPLC-ICP-MS) revealed that the predominant species present in straw was arsenate followed by arsenite and dimethylarsinic acid (DMAA). As DMAA is only present at low concentrations, it is unlikely this will greatly alter the toxicity of arsenic present in rice.