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Post-translational generation of Cá-formylglycine in Prokaryotic Sulfatsases by Radical SAM-Proteins / Posttranslationale Bildung von Cá-formylglycine in Prokaryotischen bakterieller Sulfatasen durch Radikal-SAM-ProteineFang, Qinghua 22 January 2004 (has links)
No description available.
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Construction & Evaluation of a Reporter Gene Displaying Aldehydes on the Cell SurfaceWong, Christine 14 October 2020 (has links)
Reporter genes are often used to observe expression of promoters, which may change from its natural behaviour as a result of stress or disease states. Reporter genes are useful because they are easily detectable by a variety of imaging methods, including fluorescence microscopy techniques, magnetic resonance imaging, and positron emission tomography. Previously, methyl 5-MeO-N-aminoanthranilate (MMNA) had been synthesized as an
aldehyde-conditional fluorophore and was tested in physiological conditions to identify the Aldehydic Load of cells. Thus, it was hypothesized that a reporter protein displaying an aldehyde on the cell surface can be identified by MMNA. This reporter protein would contain a substrate recognition site for formylglycine generating enzyme (FGE) that converts a specific cysteine residue into a formylglycine residue. This will result in production of an aldehyde at the
N-terminal of the transmembrane domain of platelet derived growth factor receptor . In this way, the protein product, Aldehyde-presenting FGE-dependent Readout (Alfred), would display an aldehyde on the extracellular surface of the cell. Alfred was expressed in A549 human lung cancer cells using the Tet-On® Inducible System, which allows expression of a gene of interest by use of doxycyclin (dox) as a chemical trigger. Microscopy of Alfred-transfected cells, induced by dox and probed with MMNA, showed no difference in fluorescence between
non-transfected and Alfred-transfected cells. The overexpression of FGE to increase
thiol-to-aldehyde conversion, and the imaging of cells at longer timepoints (48 and 72 hours) to allow localization of the protein to the cell surface, were attempted. In addition, Alfred was constitutively expressed in another transfection experiment in efforts to increase gene expression. However, these efforts to evaluate Alfred did not improve the microscopy results. Western blotting confirmed FGE overexpression in transgenic cells. Blotting against the Myc-tag in Alfred showed no detected proteins in Alfred-transfected cells. In conjunction with the microscopy images, these results suggest that Alfred is not expressed and cannot be detected as a reporter gene. Comparison to previous works allows the identification of potential approaches to improve Alfred functionality, including the absence of the hemagglutinin epitope, the choice of aldehyde probe used, the choice of cell line used, and the method of analyzing microscopy. Future directives are postulated to identify sources that hinder Alfred expression, and to improve visualization of Alfred over homeostatic aldehydes.
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Kristallisation von GGA-Proteinen und röntgenkristallographische Untersuchungen am Cα-Formylglycin Generierenden Enzym / Crystallisation of GGA proteins and X-ray crystallographic studies on the Cα-Formylglycin Generating EnzymeRöser, Dirk 02 November 2006 (has links)
No description available.
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Mechanism of pFGE and FGE Retention in Endoplasmic Reticulum / Mechanismus der retention von pFGE und FGE im Endoplasmatischen ReticulumGande, Santosh Lakshmi 16 January 2007 (has links)
No description available.
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Untersuchungen zur molekularen Ursache der Multiplen Sulfatase-Defizienz: Reinigung, Funktions- und Strukturanalyse von varianten Proteinen des Formylglycin-generierenden Enzyms / The molecular cause of multiple sulfatase deficiency: cleaning, functional and structural analysis of variant proteins of formylglycine-generating enzymeMühlhausen, Helene 14 January 2015 (has links)
No description available.
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