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| Field | Value |
| Title | High Resolution Structures of Periplasmic Glucose-binding Protein of Pseudomonas putida CSV86 Reveal Structural Basis of Its Substrate Specificity |
| Names |
PANDEY, S
MODAK, A PHALE, PS BHAUMIK, P |
| Date Issued | 2016 (iso8601) |
| Abstract | Periplasmic substrate-binding proteins (SBPs) bind to the specific ligand with high affinity and mediate their transport into the cytoplasm via the cognate inner membrane ATP-binding cassette proteins. Because of low sequence identities, understanding the structural basis of substrate recognition by SBPs has remained very challenging. There are several structures available for the ligand-bound sugar SBPs, but very few unliganded structures are reported. No structural data are available for sugar SBPs from Pseudomonas sp. to date. This study reports the first high resolution crystal structures of periplasmic glucose-binding protein from Pseudomonas putida CSV86 (ppGBP) in unliganded form (2.5 ) and complexed with glucose (1.25 ) and galactose (1.8 ). Asymmetric domain closure of ppGBP was observed upon substrate binding. The ppGBP was found to have an affinity of approximate to 0.3 m for glucose. The structural analysis showed that the sugars are bound to the protein mainly by hydrogen bonds, and the loss of two strong hydrogen bonds between ppGBP and galactose compared with glucose may be responsible for lowering its affinity toward galactose. The higher stability of ppGBP-glucose complex was also indicated by an 8 degrees C increase in the melting temperature compared with unliganded form and ppGBP-galactose complex. ppGBP binds to monosaccharide, but the structural features revealed it to have an oligosaccharide-binding protein fold, indicating that during evolution the sugar binding pocket may have undergone structural modulation to accommodate monosaccharide only. |
| Genre | Article |
| Topic | SURFACE-PLASMON RESONANCE |
| Identifier | JOURNAL OF BIOLOGICAL CHEMISTRY,291(15)7844-7857 |