AGP2
- Page ID
- 5508
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- Escobar, F.V., Piwowarski, P., Salewski, J., Michael, N., Lopez, M.F., Rupp, A., Qureshi, B.M., Scheerer, P., Bartl, F., Frankenberg-Dinkel, N. and Siebert, F., 2015. A protonation-coupled feedback mechanism controls the signalling process in bathy phytochromes. Nature chemistry, 7(5), pp.423-430. pdf
- Zienicke, B., Molina, I., Glenz, R., Singer, P., Ehmer, D., Escobar, F.V., Hildebrandt, P., Diller, R. and Lamparter, T., 2013. Unusual spectral properties of bacteriophytochrome Agp2 result from a deprotonation of the chromophore in the red-absorbing form Pr. Journal of Biological Chemistry,288(44), pp.31738-31751. pdf
- Zienicke, B., Chen, L.Y., Khawn, H., Hammam, M.A., Kinoshita, H., Reichert, J., Ulrich, A.S., Inomata, K. and Lamparter, T., 2011. Fluorescence of phytochrome adducts with synthetic locked chromophores. Journal of Biological Chemistry, 286(2), pp.1103-1113. pdf
- Rottwinkel, G., Oberpichler, I. and Lamparter, T., 2010. Bathy phytochromes in rhizobial soil bacteria. Journal of bacteriology, 192(19), pp.5124-5133. pdf
- Scheerer, P., Michael, N., Park, J.H., Nagano, S., Choe, H.W., Inomata, K., Borucki, B., Krauß, N. and Lamparter, T., 2010. Light‐Induced Conformational Changes of the Chromophore and the Protein in Phytochromes: Bacterial Phytochromes as Model Systems. ChemPhysChem, 11(6), pp.1090-1105. pdf
- Inomata, K., Khawn, H., Chen, L.Y., Kinoshita, H., Zienicke, B., Molina, I. and Lamparter, T., 2009. Assembly of Agrobacterium Phytochromes Agp1 and Agp2 with Doubly Locked Bilin Chromophores†. Biochemistry, 48(12), pp.2817-2827. pdf
- Krieger, A., Molina, I., Oberpichler, I., Michael, N. and Lamparter, T., 2008. Spectral properties of phytochrome Agp2 from Agrobacterium tumefaciens are specifically modified by a compound of the cell extract. Journal of Photochemistry and Photobiology B: Biology, 93(1), pp.16-22. pdf
- Inomata, K., Noack, S., Hammam, M.A., Khawn, H., Kinoshita, H., Murata, Y., Michael, N., Scheerer, P., Krauss, N. and Lamparter, T., 2006. Assembly of synthetic locked chromophores with Agrobacterium phytochromes Agp1 and Agp2. Journal of Biological Chemistry, 281(38), pp.28162-28173. pdf
- Lamparter, T., 2006. A computational approach to discovering the functions of bacterial phytochromes by analysis of homolog distributions. BMC bioinformatics, 7(1), p.1. pdf
- Oberpichler, I., Molina, I., Neubauer, O. and Lamparter, T., 2006. Phytochromes from Agrobacterium tumefaciens: Difference spectroscopy with extracts of wild type and knockout mutants. FEBS letters, 580(2), pp.437-442. pdf
- Lamparter, T., Michael, N., Mittmann, F. and Esteban, B., 2002. Phytochrome from Agrobacterium tumefaciens has unusual spectral properties and reveals an N-terminal chromophore attachment site. Proceedings of the National Academy of Sciences, 99(18), pp.11628-11633. pdf