Quantitative, chemically specific imaging of selenium transformation in plants.

Quantitative, chemically specific images of biological systems would be invaluable in unraveling the bioinorganic chemistry of biological tissues. Here we report the spatial distribution and chemical forms of selenium in Astragalus bisulcatus (two-grooved poison or milk vetch), a plant capable of accumulating up to 0.65% of its shoot dry biomass as Se in its natural habitat. By selectively tuning incident x-ray energies close to the Se K-absorption edge, we have collected quantitative, 100-microm-resolution images of the spatial distribution, concentration, and chemical form of Se in intact root and shoot tissues. To our knowledge, this is the first report of quantitative concentration-imaging of specific chemical forms. Plants exposed to 5 microM selenate for 28 days contained predominantly selenate in the mature leaf tissue at a concentration of 0.3-0.6 mM, whereas the young leaves and the roots contained organoselenium almost exclusively, indicating that the ability to biotransform selenate is either inducible or developmentally specific. While the concentration of organoselenium in the majority of the root tissue was much lower than that of the youngest leaves (0.2-0.3 compared with 3-4 mM), isolated areas on the extremities of the roots contained concentrations of organoselenium an order of magnitude greater than the rest of the root. These imaging results were corroborated by spatially resolved x-ray absorption near-edge spectra collected from selected 100 x 100 microm(2) regions of the same tissues.

[1]  M. J. Pimenta,et al.  S-Methylmethionine Plays a Major Role in Phloem Sulfur Transport and Is Synthesized by a Novel Type of Methyltransferase , 1999, Plant Cell.

[2]  A. Böck,et al.  A Family of S-Methylmethionine-dependent Thiol/Selenol Methyltransferases , 1999, The Journal of Biological Chemistry.

[3]  Terry,et al.  Overexpression of ATP sulfurylase in indian mustard leads to increased selenate uptake, reduction, and tolerance , 1999, Plant physiology.

[4]  R. M. Miller,et al.  X-ray imaging and microspectroscopy of plants and fungi. , 1998, Journal of synchrotron radiation.

[5]  S. Bajt,et al.  Selenium Diffusion and Reduction at the Water−Sediment Boundary: Micro-XANES Spectroscopy of Reactive Transport , 1998 .

[6]  A. Tsuchiyama,et al.  Chemical speciation of geological samples by micro XANES techniques , 1998 .

[7]  I. Schröder,et al.  Purification and Characterization of the Selenate Reductase from Thauera selenatis * , 1997, The Journal of Biological Chemistry.

[8]  I. Goldman,et al.  Antagonistic Relationship between Selenate and Sulfate Uptake in Onion (Allium cepa): Implications for the Production of Organosulfur and Organoselenium Compounds in Plants , 1997 .

[9]  G. Giordano,et al.  Tellurite reductase activity of nitrate reductase is responsible for the basal resistance of Escherichia coli to tellurite. , 1997, Microbiology.

[10]  A. Setya,et al.  Sulfate reduction in higher plants: molecular evidence for a novel 5'-adenylylsulfate reductase. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[11]  I. Pickering,et al.  Selenium Transformations in Ponded Sediments , 1996 .

[12]  Alan J. M. Baker,et al.  Free histidine as a metal chelator in plants that accumulate nickel , 1996, Nature.

[13]  D. E. Salt,et al.  Mechanisms of Cadmium Mobility and Accumulation in Indian Mustard , 1995, Plant physiology.

[14]  I. Pickering,et al.  Quantitative Speciation of Selenium in Soils Using X-ray Absorption Spectroscopy. , 1995, Environmental science & technology.

[15]  S. Bajt,et al.  Synchrotron x‐ray fluorescence microprobe: Quantification and mapping of mixed valence state samples using micro‐XANES , 1995 .

[16]  S. Sutton,et al.  Manganese oxidation states in Gaeumannomyces-infested wheat rhizospheres probeb by micro-XANES spectroscopy , 1995 .

[17]  Alan J. M. Baker,et al.  TERRESTRIAL HIGHER PLANTS WHICH HYPERACCUMULATE METALLIC ELEMENTS. A REVIEW OF THEIR DISTRIBUTION, ECOLOGY AND PHYTOCHEMISTRY , 1989 .

[18]  M. C. Nichols,et al.  Elemental and chemical-state imaging using synchrotron radiation. , 1986, Applied optics.

[19]  J. Burnell Selenium Metabolism in Neptunia amplexicaulis. , 1981, Plant physiology.

[20]  J. Anderson,et al.  Comparative enzymology of the adenosine triphosphate sulphurylases from leaf tissue of selenium-accumulator and non-accumulator plants. , 1974, The Biochemical journal.

[21]  S. Nigam,et al.  Seleno amino compounds from Astragalus bisculcatus. Isolation and identification of gamma-L-glutamyl-Se-methyl-seleno-L-cysteine and Se-methylseleno-L-cysteine. , 1969, Biochimica et biophysica acta.

[22]  A. Shrift Aspects of selenium metabolism in higher plants , 1969 .

[23]  S. Trelease,et al.  Seleno-Amino Acid Found in Astragalus bisulcatus , 1960, Science.

[24]  J. H. Draize,et al.  Certain poisonous plants of wyoming activated by selenium and their association with respect to soil types , 1934 .