1. Construction and validation of an atomic model for bacterial TSPO from electron microscopy density, evolutionary constraints, and biochemical and biophysical data.
- Author
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Hinsen, Konrad, Vaitinadapoule, Aurore, Ostuni, Mariano A., Etchebest, Catherine, and Lacapere, Jean-Jacques
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BACTERIAL proteins , *ELECTRON microscopy , *CHROMOSOMAL translocation , *BACTERIAL cell walls , *BIOCHEMISTRY , *BIOPHYSICS , *RHODOBACTER sphaeroides - Abstract
The 18 kDa protein TSPO is a highly conserved transmembrane protein found in bacteria, yeast, animals and plants. TSPO is involved in a wide range of physiological functions, among which the transport of several molecules. The atomic structure of monomeric ligand-bound mouse TSPO in detergent has been published recently. A previously published low-resolution structure of Rhodobacter sphaeroides TSPO, obtained from tubular crystals with lipids and observed in cryo-electron microscopy, revealed an oligomeric structure without any ligand. We analyze this electron microscopy density in view of available biochemical and biophysical data, building a matching atomic model for the monomer and then the entire crystal. We compare its intra- and inter-molecular contacts with those predicted by amino acid covariation in TSPO proteins from evolutionary sequence analysis. The arrangement of the five transmembrane helices in a monomer of our model is different from that observed for the mouse TSPO. We analyze possible ligand binding sites for protoporphyrin, for the high-affinity ligand PK 11195, and for cholesterol in TSPO monomers and/or oligomers, and we discuss possible functional implications. [ABSTRACT FROM AUTHOR]
- Published
- 2015
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