Potassium ion channels utilize a highly selective filter to rapidly transport K+ ions across cellular membranes. This selectivity filter is composed of four binding sites which display almost equal electron density in crystal structures with high potassium ion concentrations. This electron density can be interpreted to reflect a superposition of alternating potassium ion and water occupied states or as adjacent potassium ions. Here, we use single wavelength anomalous dispersion (SAD) X-ray diffraction data collected near the potassium absorption edge to show experimentally that all ion binding sites within the selectivity filter are fully occupied by K+ ions. These data support the hypothesis that potassium ion transport occurs by direct Coulomb knock-on, and provide an example of solving the phase problem by K-SAD.
In this paper we describe the engineering and X-ray crystal structure of Thermal Green Protein (TGP), an extremely stable, highly soluble, non-aggregating green fluorescent protein. TGP is a soluble variant of the fluorescent protein eCGP123, which despite being highly stable, has proven to be aggregation-prone. The X-ray crystal structure of eCGP123, also determined within the context of this paper, was used to carry out rational surface engineering to improve its solubility, leading to TGP. The approach involved simultaneously eliminating crystal lattice contacts while increasing the overall negative charge of the protein. Despite intentional disruption of lattice contacts and introduction of high entropy glutamate side chains, TGP crystallized readily in a number of different conditions and the X-ray crystal structure of TGP was determined to 1.9 Å resolution. The structural reasons for the enhanced stability of TGP and eCGP123 are discussed. We demonstrate the utility of using TGP as a fusion partner in various assays and significantly, in amyloid assays in which the standard fluorescent protein, EGFP, is undesirable because of aberrant oligomerization.
It is demonstrated that using three-dimensional profile fitting of Bragg peaks increases the accuracy and resolution of neutron crystallographic data collected from proteins and reveals new features in nuclear density maps calculated from these data.
The monobactam antibiotic aztreonam is used to treat cystic fibrosis patients with chronic pulmonary infections colonized by Pseudomonas aeruginosa strains expressing CTX-M extended-spectrum β-lactamases. The protonation states of active-site residues that are responsible for hydrolysis have been determined previously for the apo form of a CTX-M β-lactamase but not for a monobactam acyl-enzyme intermediate. Here we used neutron and high-resolution X-ray crystallography to probe the mechanism by which CTX-M extended-spectrum β-lactamases hydrolyze monobactam antibiotics. In these first reported structures of a class A β-lactamase in an acyl-enzyme complex with aztreonam, we directly observed most of the hydrogen atoms (as deuterium) within the active site. Although Lys 234 is fully protonated in the acyl intermediate, we found that Lys 73 is neutral. These findings are consistent with Lys 73 being able to serve as a general base during the acylation part of the catalytic mechanism, as previously proposed.
The emergence and dissemination of bacterial resistance to β-lactam antibiotics via β-lactamase enzymes is a serious problem in clinical settings, often leaving few treatment options for infections resulting from multidrug-resistant superbugs. Understanding the catalytic mechanism of βlactamases is important for developing strategies to overcome resistance. Binding of a substrate in the active site of an enzyme can alter the conformations and pK a s of catalytic residues, thereby contributing to enzyme catalysis. Here we report X-ray and neutron crystal structures of the class A Toho-1 β-lactamase in the apo form and an X-ray structure of a Michaelis-like complex with the cephalosporin antibiotic cefotaxime in the active site. Comparison of these structures reveals that substrate binding induces a series of changes. The side chains of conserved residues important in catalysis, Lys73 and Tyr105, and the main chain of Ser130 alter their conformations, with Nζ of Lys73 moving closer to the position of the conserved catalytic nucleophile Ser70. This movement of Lys73 closer to Ser70 is consistent with proton transfer between the two residues prior to acylation. In combination with the tightly bound catalytic water molecule located between Glu166 and the position of Ser70, the enzyme is primed for catalysis when Ser70 is activated for nucleophilic attack of the β-lactam ring. Quantum mechanical/molecular mechanical (QM/MM) free energy simulations of models of the wild-type enzyme show that proton transfer from the Nζ of Lys73 to the Oε2 atom of Glu166 is more thermodynamically favorable than when it is absent. Taken together, our findings indicate that substrate binding enhances the favorability of the initial proton transfer steps that precede the formation of the acyl-enzyme intermediate.
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