Halogen bonding at the active sites of human cathepsin†L and MEK1 kinase: efficient interactions in different environments.

In two series of small-molecule ligands, one inhibiting human cathepsin L (hcatL) and the other MEK1 kinase, biological affinities were found to strongly increase when an aryl ring of the inhibitors is substituted with the larger halogens Cl, Br, and I, but to decrease upon F substitution. X-ray co-crystal structure analyses revealed that the higher halides engage in halogen bonding (XB) with a backbone C=O in the S3 pocket of hcatL and in a back pocket of MEK1. While the S3 pocket is located at the surface of the enzyme, which provides a polar environment, the back pocket in MEK1 is deeply buried in the protein and is of pronounced apolar character. This study analyzes environmental effects on XB in protein-ligand complexes. It is hypothesized that energetic gains by XB are predominantly not due to water replacements but originate from direct interactions between the XB donor (Caryl-X) and the XB acceptor (C=O) in the correct geometry. New X-ray co-crystal structures in the same crystal form (space group P2(1)2(1)2(1)) were obtained for aryl chloride, bromide, and iodide ligands bound to hcatL. These high-resolution structures reveal that the backbone C=O group of Gly61 in most hcatL co-crystal structures maintains water solvation while engaging in XB. An aryl-CF3-substituted ligand of hcatL with an unexpectedly high affinity was found to adopt the same binding geometry as the aryl halides, with the CF3 group pointing to the C=O group of Gly61 in the S3 pocket. In this case, a repulsive F2C-F⋅⋅⋅O=C contact apparently is energetically overcompensated by other favorable protein-ligand contacts established by the CF3 group.

The crystal structures of human S100B in the zinc- and calcium-loaded state at three pH values reveal zinc ligand swapping.

S100B is a homodimeric zinc-, copper-, and calcium-binding protein of the family of EF-hand S100 proteins. Zn(2+) binding to S100B increases its affinity towards Ca(2+) as well as towards target peptides and proteins. Cu(2+) and Zn(2+) bind presumably to the same site in S100B. We determined the structures of human Zn(2+)- and Ca(2+)-loaded S100B at pH 6.5, pH 9, and pH 10 by X-ray crystallography at 1.5, 1.4, and 1.65Å resolution, respectively. Two Zn(2+) ions are coordinated tetrahedrally at the dimer interface by His and Glu residues from both subunits. The crystal structures revealed that ligand swapping occurs for one of the four ligands in the Zn(2+)-binding sites. Whereas at pH 9, the Zn(2+) ions are coordinated by His15, His25, His 85', and His 90', at pH 6.5 and pH 10, His90' is replaced by Glu89'. The results document that the Zn(2+)-binding sites are flexible to accommodate other metal ions such as Cu(2+). Moreover, we characterized the structural changes upon Zn(2+) binding, which might lead to increased affinity towards Ca(2+) as well as towards target proteins. We observed that in Zn(2+)-Ca(2+)-loaded S100B the C-termini of helix IV adopt a distinct conformation. Zn(2+) binding induces a repositioning of residues Phe87 and Phe88, which are involved in target protein binding. This article is part of a Special Issue entitled: 11th European Symposium on Calcium.

Structural basis for ligand recognition and activation of RAGE.

The receptor for advanced glycation end products (RAGE) is a pattern recognition receptor involved in inflammatory processes and is associated with diabetic complications, tumor outgrowth, and neurodegenerative disorders. RAGE induces cellular signaling events upon binding of a variety of ligands, such as glycated proteins, amyloid-ß, HMGB1, and S100 proteins. The X-ray crystal structure of the VC1 ligand-binding region of the human RAGE ectodomain was determined at 1.85 Å resolution. The VC1 ligand-binding surface was mapped onto the structure from titrations with S100B monitored by heteronuclear NMR spectroscopy. These NMR chemical shift perturbations were used as input for restrained docking calculations to generate a model for the VC1-S100B complex. Together, the arrangement of VC1 molecules in the crystal and complementary biochemical studies suggest a role for self-association in RAGE function. Our results enhance understanding of the functional outcomes of S100 protein binding to RAGE and provide insight into mechanistic models for how the receptor is activated.

Crystallization and calcium/sulfur SAD phasing of the human EF-hand protein S100A2.

Human S100A2 is an EF-hand protein and acts as a major tumour suppressor, binding and activating p53 in a Ca2+-dependent manner. Ca2+-bound S100A2 was crystallized and its structure was determined based on the anomalous scattering provided by six S atoms from methionine residues and four calcium ions present in the asymmetric unit. Although the diffraction data were recorded at a wavelength of 0.90 A, which is usually not assumed to be suitable for calcium/sulfur SAD, the anomalous signal was satisfactory. A nine-atom substructure was determined at 1.8 A resolution using SHELXD, and SHELXE was used for density modification and phase extension to 1.3 A resolution. The electron-density map obtained was well interpretable and could be used for automated model building by ARP/wARP.

Crystal structure of ultralente--a microcrystalline insulin suspension.

Ultralente insulin has been one of the commercially most important insulin preparations in diabetes treatment over the last 50 years. It is a suspension of insulin microcrystals which dissolve slowly following subcutaneous injection. Because of the small crystal size of about 25 x 25 x 5 microm(3) the atomic structure has been elusive until now. Here we present the crystal structures from Ultralente and their precursor microcrystals from the industrial manufacturing process. During this process insulin undergoes a conformational change within the microcrystals. Both structures show canonical folding of the insulin molecules but exhibit a number of new features when compared with other insulin structures. Surprisingly, we found that the Ultralente crystals bind the conservation agent methylparaben, which slows down dissolution of the crystals and thus contributes to the long duration of action.

Crystallization and preliminary X-ray analysis of the Thermoplasma acidophilum 20S proteasome in complex with protein substrates.

The 20S proteasome is a 700 kDa barrel-shaped proteolytic complex that is traversed by an internal channel which widens into three cavities: two antechambers and one central chamber. Entrance to the complex is restricted by the narrow opening of the channel, which only allows unfolded substrates to reach the active sites located within the central cavity. The X-ray structures of 20S proteasomes from different organisms with and without inhibitors bound have led to a detailed knowledge of their structure and proteolytic function. Nevertheless, the mechanisms that underlie substrate translocation into the 20S proteasome and the role of the antechambers remain elusive. To investigate putative changes within the proteasome that occur during substrate translocation, ;host-guest' complexes between the Thermoplasma acidophilum 20S proteasomes and either cytochrome c (cyt c) or green fluorescent protein (GFP) were produced and crystallized. Orthorhombic crystals belonging to space group P2(1)2(1)2(1), with unit-cell parameters a = 116, b = 207, c = 310 A (cyt c) and a = 116, b = 206, c = 310 A (GFP), were formed and X-ray diffraction data were collected to 3.4 A (cyt c) and 3.8 A (GFP) resolution.

Crystal structure of Ca2+ -free S100A2 at 1.6-A resolution.

S100A2 is an EF hand-containing Ca(2+)-binding protein of the family of S100 proteins. The protein is localized exclusively in the nucleus and is involved in cell cycle regulation. It attracted most interest by its function as a tumor suppressor via p53 interaction. We determined the crystal structure of homodimeric S100A2 in the Ca(2+)-free state at 1.6-A resolution. The structure revealed structural differences between subunits A and B, especially in the conformation of a loop that connects the N- and C-terminal EF hands and represents a part of the target-binding site in S100 proteins. Analysis of the hydrogen bonding network and molecular dynamics calculations indicate that one of the two observed conformations is more stable. The structure revealed Na(+) bound to each N-terminal EF hand of both subunits coordinated by oxygen atoms of the backbone carbonyl and water molecules. Comparison with the structures of Ca(2+)-free S100A3 and S100A6 suggests that Na(+) might occupy the S100-specific EF hand in the Ca(2+)-free state.

Purification and crystallization of the human EF-hand tumour suppressor protein S100A2.

S100A2 is a Ca(2+)-binding EF-hand protein that is mainly localized in the nucleus. There, it acts as a tumour suppressor by binding and activating p53. Wild-type S100A2 and a S100A2 variant lacking cysteines have been purified. CD spectroscopy showed that there are no changes in secondary-structure composition. The S100A2 mutant was crystallized in a calcium-free form. The crystals, with dimensions 30 x 30 x 70 microm, diffract to 1.7 A and belong to space group P2(1)2(1)2(1), with unit-cell parameters a = 43.5, b = 57.8, c = 59.8 A, alpha = beta = gamma = 90 degrees. Preliminary analysis of the X-ray data indicates that there are two subunits per asymmetric unit.

Crystallization of the NADH-oxidizing domain of the Na+-translocating NADH:ubiquinone oxidoreductase from Vibrio cholerae.

The Na+-translocating NADH:quinone oxidoreductase (Na+-NQR) from pathogenic and marine bacteria is a respiratory complex that couples the exergonic oxidation of NADH by quinone to the transport of Na+ across the membrane. The NqrF subunit oxidizes NADH and transfers the electrons to other redox cofactors in the enzyme. The FAD-containing domain of NqrF has been expressed, purified and crystallized. The purified NqrF FAD domain exhibited high rates of NADH oxidation and contained stoichiometric amounts of the FAD cofactor. Initial crystallization of the flavin domain was achieved by the sitting-drop technique using a Cartesian MicroSys4000 robot. Optimization of the crystallization conditions yielded yellow hexagonal crystals with dimensions of 30 x 30 x 70 microm. The protein mainly crystallizes in long hexagonal needles with a diameter of up to 30 microm. Crystals diffract to 2.8 A and belong to space group P622, with unit-cell parameters a = b = 145.3, c = 90.2 A, alpha = beta = 90, gamma = 120 degrees.

Structural model of MalK, the ABC subunit of the maltose transporter of Escherichia coli: implications for mal gene regulation, inducer exclusion, and subunit assembly.

We are presenting a three-dimensional model of MalK, the ABC subunit of the maltose transporter from Escherichia coli and Salmonella typhimurium. It is based on the recently published crystal structure of the closely related Thermococcus litoralis MalK. The model was used to identify the position of mutations affecting the different functions of the ABC subunit. Six malK point mutations were isolated specifically affecting the interaction with MalT, the transcriptional regulator of the maltose system. They were mapped on the structural model and define a MalT interaction site that is located on an exposed surface of the C-terminal regulatory domain. Published point mutations that confer an inducer exclusion insensitive phenotype form a patch adjacent to and oriented perpendicularly to the MalT interaction site. Three sequence motifs were identified and visualized that are highly conserved among ABC subunits with extended C termini. They form a subdomain between the regulatory and ATPase domain and might play an important role in signal transduction events between these two domains. Mutations in this domain remain fully active in MalT regulation but cause transport defects. In addition, amino acids that have previously been shown to be involved in the interaction with the transmembranous subunits MalF and MalG and that fall into the highly conserved N-terminal ATPase domain were visualized. The validity of the modeled MalK structure was verified by structure-directed mutagenesis of amino acids located within the proposed MalK-MalT interaction site.