Zygmunt S. Derewenda

The structure of the saccharide-binding site of concanavalin A.

A complex of concanavalin A with methyl alpha‐D‐mannopyranoside has been crystallized in space group P212121 with a = 123.9 A, b = 129.1 A and c = 67.5 A. X‐ray diffraction intensities to 2.9 A resolution have been collected on a Xentronics/Nicolet area detector. The structure has been solved by molecular replacement where the starting model was based on refined coordinates of an I222 crystal of saccharide‐free concanavalin A. The structure of the saccharide complex was refined by restrained least‐squares methods to an R‐factor value of 0.19. In this crystal form, the asymmetric unit contains four protein subunits, to each of which a molecule of mannoside is bound in a shallow crevice near the surface of the protein. The methyl alpha‐D‐mannopyranoside molecule is bound in the C1 chair conformation 8.7 A from the calcium‐binding site and 12.8 A from the transition metal‐binding site. A network of seven hydrogen bonds connects oxygen atoms O‐3, O‐4, O‐5 and O‐6 of the mannoside to residues Asn14, Leu99, Tyr100, Asp208 and Arg228. O‐2 and O‐1 of the mannoside extend into the solvent. O‐2 is hydrogen‐bonded through a water molecule to an adjacent asymmetric unit. O‐1 is not involved in any hydrogen bond and there is no fixed position for its methyl substituent.

Toward rational protein crystallization : A Web server for the design of crystallizable protein variants

Growing well‐diffracting crystals constitutes a serious bottleneck in structural biology. A recently proposed crystallization methodology for “stubborn crystallizers” is to engineer surface sequence variants designed to form intermolecular contacts that could support a crystal lattice. This approach relies on the concept of surface entropy reduction (SER), i.e., the replacement of clusters of flexible, solvent‐exposed residues with residues with lower conformational entropy. This strategy minimizes the loss of conformational entropy upon crystallization and renders crystallization thermodynamically favorable. The method has been successfully used to crystallize more than 15 novel proteins, all stubborn crystallizers. But the choice of suitable sites for mutagenesis is not trivial. Herein, we announce a Web server, the surface entropy reduction prediction server (SERp server), designed to identify mutations that may facilitate crystallization. Suggested mutations are predicted based on an algorithm incorporating a conformational entropy profile, a secondary structure prediction, and sequence conservation. Minor considerations include the nature of flanking residues and gaps between mutation candidates. While designed to be used with default values, the server has many user‐controlled parameters allowing for considerable flexibility. Within, we discuss (1) the methodology of the server, (2) how to interpret the results, and (3) factors that must be considered when selecting mutations. We also attempt to benchmark the server by comparing the servers predictions with successful SER structures. In most cases, the structure yielding mutations were easily identified by the SERp server. The server can be accessed at http://www.doe‐mbi.ucla.edu/Services/SER.

News from the interface: the molecular structures of triacyglyceride lipases

Neutral lipases constitute one of the most ubiquitous and diverse families of enzymes. The recently solved crystal structures of three lipases show that enzymatic hydrolysis occurs with the assistance of a catalytic triad, which is structurally reminiscent of serine proteinases. However, these lipases only become active at the oil-water interface through a conformational change that exposes the active centre of the enzyme.

Entropy and surface engineering in protein crystallization.

Protein crystallization remains a key limiting step in the characterization of the atomic structures of proteins and their complexes by X-ray diffraction methods. Current data indicate that standard screening procedures applied to soluble well folded prokaryotic proteins yield X-ray diffraction crystals with an approximately 20% success rate and for eukaryotic proteins this figure may be significantly lower. Protein crystallization is predominantly dependent on entropic effects and the driving force appears to be the release of ordered water from the sites of crystal contacts. This is countered by the entropic cost of ordering of protein molecules and by the loss of conformational freedom of side chains involved in the crystal contacts. Mutational surface engineering designed to create patches with low conformational entropy and thereby conducive to formation of crystal contacts promises to be an effective tool allowing direct enhancement of the success rate of macromolecular crystallization.

Structure and Function of Lipases

Publisher Summary This chapter focuses on the current progress in crystallographic studies of neutral lipases and the impact of these studies have on understanding of the structure-function relationships in lipolytic enzymes. Lipid metabolism begins with a meal, and after a preliminary digestion in the stomach, the gastric contents are sprayed into the intestine where dietary lipids combine with the biliary secretion to form an emulsion providing a large lipid-aqueous interface where lipases may act. Triglyceride hydrolysis is accomplished principally by pancreatic lipase, which together with colipase, binds to the interface where it has access to the lipid. The three-dimensional structure of this enzyme as well as the structures of several fungal lipases is described. The structural basis of the enzymatic hydrolysis of the ester bond and activation of lipases at an oil/water interface is focused. Possible relationships between lipases and other serine hydrolases are discussed in the context of structural comparisons. The chapter also describes the currently available structural database and provides fascinating insights into the mechanism of interfacial activation and ester bond hydrolysis by this group of lipases.

Crystal structure of brefeldin A esterase, a bacterial homolog of the mammalian hormone-sensitive lipase.

Brefeldin A esterase (BFAE), a detoxifying enzyme isolated from Bacillus subtilis, hydrolyzes and inactivates BFA, a potent fungal inhibitor of intracellular vesicle-dependent secretory transport and poliovirus RNA replication. We have solved the crystal structure of BFAE and we discovered that the previously reported amino acid sequence was in serious error due to frame shifts in the cDNA sequence. The correct sequence, inferred from the experimentally phased electron density map, revealed that BFAE is a homolog of the mammalian hormone sensitive lipase (HSL). It is a canonical α/β hydrolase with two insertions forming the substrate binding pocket. The enzyme contains a lipase-like catalytic triad, Ser 202, Asp 308 and His 338, consistent with mutational studies that implicate the homologous Ser 424, Asp 693 and His 723 in the catalytic triad in human HSL.

The name is bond — H bond

The hydrogen bond plays a critical role in diverse biological phenomena. Although discovered 90 years ago, the precise chemical nature of this unique interaction has remained in dispute. A recent Compton-scattering experiment, however, strongly supports a partially covalent picture of the hydrogen bond.

The Crystal Structure of a Major Dust Mite Allergen Der p 2, and its Biological Implications

The crystal structure of the common house mite (Dermatophagoides sp.) Der p 2 allergen was solved at 2.15 A resolution using the MAD phasing technique, and refined to an R-factor of 0.209. The refined atomic model, which reveals an immunoglobulin-like tertiary fold, differs in important ways from the previously described NMR structure, because the two beta-sheets are significantly further apart and create an internal cavity, which is occupied by a hydrophobic ligand. This interaction is structurally reminiscent of the binding of a prenyl group by a regulatory protein, the Rho guanine nucleotide exchange inhibitor. The crystal structure suggests that binding of non-polar molecules may be essential to the physiological function of the Der p 2 protein.

Crystal structure of the Escherichia coli thioesterase II, a homolog of the human Nef binding enzyme

Here we report the solution and refinement at 1.9 Å resolution of the crystal structure of the Escherichia coli medium chain length acyl-CoA thioesterase II. This enzyme is a close homolog of the human protein that interacts with the product of the HIV-1 Nef gene, sharing 45% amino acid sequence identity with it. The structure of the E. coli thioesterase II reveals a new tertiary fold, a ‘double hot dog’, showing an internal repeat with a basic unit that is structurally similar to the recently described β-hydroxydecanoyl thiol ester dehydrase. The catalytic site, inferred from the crystal structure and verified by site directed mutagenesis, involves novel chemistry and includes Asp 204, Gln 278 and Thr 228, which synergistically activate a nucleophilic water molecule.

Protein Crystallization by surface entropy reduction: optimization of the SER strategy

A strategy of rationally engineering protein surfaces with the aim of obtaining mutants that are distinctly more susceptible to crystallization than the wild-type protein has previously been suggested. The strategy relies on replacing small clusters of two to three surface residues characterized by high conformational entropy with alanines. This surface entropy reduction (or SER) method has proven to be an effective salvage pathway for proteins that are difficult to crystallize. Here, a systematic comparison of the efficacy of using Ala, His, Ser, Thr and Tyr to replace high-entropy residues is reported. A total of 40 mutants were generated and screened using two different procedures. The results reaffirm that alanine is a particularly good choice for a replacement residue and identify tyrosines and threonines as additional candidates that have considerable potential to mediate crystal contacts. The propensity of these mutants to form crystals in alternative screens in which the normal crystallization reservoir solutions were replaced with 1.5 M NaCl was also examined. The results were impressive: more than half of the mutants yielded a larger number of crystals with salt as the reservoir solution. This method greatly increased the variety of conditions that yielded crystals. Taken together, these results suggest a powerful crystallization strategy that combines surface engineering with efficient screening using standard and alternate reservoir solutions.