Abstract
Conformational changes of periplasmic binding proteins are essential for their function in chemotaxis and transport. The allose-binding protein from Escherichia coli is, like other receptors in its family, composed of two alpha/beta domains joined by a three-stranded hinge. In the previously determined structure of the closed, ligand-bound form (Chaudhuri, B. N., Ko, J., Park, C., Jones, T. A., and Mowbray, S. L. (1999) J. Mol. Biol. 286, 1519-1531), the ligand-binding site is buried between the two domains. We report here the structures of three distinct open, ligand-free forms of this receptor, one solved at 3.1-A resolution and two others at 1.7-A resolution. Together, these allow a description of the conformational changes associated with ligand binding. A few large, coupled torsional changes in the hinge strands are sufficient to generate the overall bending motion, with only minor disruption of the individual domains. Integral water molecules appear to act as structural "ball bearings" in this process. The conformational changes of the related ribose-binding protein follow a distinct pattern. The observed differences between the two proteins can be interpreted in the context of changes in sequence and in crystal packing and provide new insights into the nature of hinge bending motion in this class of periplasmic binding proteins.
Highlights
Conformational changes of periplasmic binding proteins are essential for their function in chemotaxis and transport
In each open form, the two domains had a similar set of packing interactions that were not present in the closed form, and that would be expected to stabilize them in preference to other possible open conformations
ALBP was chosen for a detailed study of conformational changes because of its 35% sequence identity to RBP, the only other member of the subfamily for which ligand-associated conformational changes have been explored [17]
Summary
Conformational changes of periplasmic binding proteins are essential for their function in chemotaxis and transport. We report here the structures of three distinct open, ligand-free forms of this receptor, one solved at 3.1-Å resolution and two others at 1.7-Å resolution. Together, these allow a description of the conformational changes associated with ligand binding. Binding of a small molecule ligand to the periplasmic proteins favors their closure via large scale hinge-bending motions [6]. These movements are required for productive interactions with the cognate membrane permeases and, in some cases, with membrane-bound chemotaxis receptors as well.
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