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Arabidopsis thaliana β1,2-xylosyltransferase: an unusual glycosyltransferase with the potential to act at multiple stages of the plant N-glycosylation pathway

XylT (beta1,2-xylosyltransferase) is a unique Golgi-bound glycosyltransferase that is involved in the biosynthesis of glycoprotein-bound N-glycans in plants. To delineate the catalytic domain of XylT, a series of N-terminal deletion mutants was heterologously expressed in insect cells. Whereas the first 54 residues could be deleted without affecting the catalytic activity of the enzyme, removal of an additional five amino acids led to the formation of an inactive protein. Characterization of the N-glycosylation status of recombinant XylT revealed that all three potential N-glycosylation sites of the protein are occupied by N-linked oligosaccharides. However, an unglycosylated version of the enzyme displayed substantial catalytic activity, demonstrating that N-glycosylation is not essential for proper folding of XylT. In contrast with most other glycosyltransferases, XylT is enzymatically active in the absence of added metal ions. This feature is not due to any metal ion directly associated with the enzyme. The precise acceptor substrate specificity of XylT was assessed with several physiologically relevant compounds and the xylosylated reaction products were subsequently tested as substrates of other Golgi-resident glycosyltransferases. These experiments revealed that the substrate specificity of XylT permits the enzyme to act at multiple stages of the plant N-glycosylation pathway.

Oxidative protein folding and unfolded protein response elicit differing redox regulation in endoplasmic reticulum and cytosol of yeast.

Oxidative protein folding can exceed the cellular secretion machinery, inducing the unfolded protein response (UPR). Sustained endoplasmic reticulum (ER) stress leads to cell stress and disease, as described for Alzheimer, Parkinson, and diabetes mellitus, among others. It is currently assumed that the redox state of the ER is optimally balanced for formation of disulfide bonds using glutathione as the main redox buffer and that UPR causes a reduction of this organelle. The direct effect of oxidative protein folding in the ER, however, has not yet been dissected from UPR regulation. To measure in vivo redox conditions in the ER and cytosol of the yeast model organism Pichia pastoris we targeted redox-sensitive roGFP variants to the respective organelles. Thereby, we clearly demonstrate that induction of the UPR causes reduction of the cytosol in addition to ER reduction. Similarly, a more reduced redox state of the cytosol, but not of the ER, is observed during oxidative protein folding in the ER without UPR induction, as demonstrated by overexpressing genes of disulfide bond-rich secretory proteins such as porcine trypsinogen or protein disulfide isomerase (PDI1) and ER oxidase (ERO1). Cytosolic reduction seems not to be caused by the action of glutathione reductase (GLR1) and could not be compensated for by overexpression of cytosolic glutathione peroxidase (GPX1). Overexpression of GPX1 and PDI1 oxidizes the ER and increases the secretion of correctly folded proteins, demonstrating that oxidative protein folding per se is enhanced by a more oxidized ER and is counterbalanced by a more reduced cytosol. As the total glutathione concentration of these strains does not change significantly, but the ratio of GSH to GSSG is altered, either transport or redox signaling between the glutathione pools of ER and cytosol is assumed. These data clearly demonstrate that protein folding and ER stress have a severe impact on the cytosolic redox balance, which may be a major factor during development of folding-related diseases.

Determination of Glyphosate and AMPA in Three Representative Agricultural Austrian Soils with a HPLC-MS/MS Method

We developed a novel method to quantify adsorbed glyphosate and AMPA in soils based on an extraction utilizing Na-tetraborate, an SPE clean-up step, and subsequent LC-MS detection. Reversed phase-based separation of glyphosate and AMPA was realized after FMOC-derivatization. The quantification involved external calibration and 1,2–13C, 15N- labeled glyphosate as well as 13C, 15N labeled AMPA as internal standards. The optimum recovery for extraction was obtained with 40 mM Na-tetraborate. The method was applied in three representative soils (Kirchberg, Phyra, and Pixendorf, Austria) where glyphosate was applied by standard agricultural practices. The recovery for glyphosate extracted with 40 mM Na-tetraborate buffer was 93.5% (RSD <2%) for glyphosate at Kirchberg-cambisol; 95.7% (RSD < 2%) at Pixendorf- chernozem and 79.1% (RSD <7%) at Phyra-stagnosol. The corresponding values for AMPA were 92.4% (RSD <2%) at Kirchberg, 98.1% (RSD <2%) at Pixendorf and 69.9% (RSD <4%) at Phyra. The limits of detection for glyphosate were 6.8 μg kg−1(RSD <10%) at Kirchberg, 4.3 μg kg−1 (RSD <10%) at Pixendorf, and 46.5 μg kg−1 (RSD <7%) at Phyra. The limits of detection for AMPA were 26.7 μg kg−1 (RSD <10%) at Kirchberg, 25.2 μg kg−1 (RSD <10%) at Pixendorf, and 120.3 μg kg−1 (RSD <9%) at Phyra. Accordingly, the limits of quantification were 22.7 μg kg−1(RSD <5%) for glyphosate, and 88.9 μg kg−1 (RSD <2%) for AMPA at Kirchberg and respectively 14.4 μg kg−1 (RSD <6%) and 84 μg kg−1 (RSD <5%) at Pixendorf and 13.8 μg kg−1 (RSD <6%) and 87.2 μg kg−1 (RSD <8%) at Phyra. Both substances in the soils were lower than the LOQ before applying the herbicide Roundup. The influence of higher contents of iron oxides, clay, and acidic pH, resulting in a more pronounced adsorption of glyphosate and AMPA in the soils of Phyra and Kirchberg, is demonstrated.