Crystal engineering: deletion mutagenesis of the 24 kDa fragment of the DNA gyrase B subunit from Staphylococcus aureus.

The 24 kDa fragment of DNA gyrase B from Staphylococcus aureus was expressed in Escherichia coli and purified for crystallization. Crystals of the wild-type protein grew in the presence of cyclothialidine but proved difficult to reproduce. In order to improve the crystallization, the flexible regions of the protein were deleted by mutagenesis. The mutant proteins were analyzed by differential scanning calorimetry and the most stable mutants produced crystals. It was possible to reproducibly grow single well defined crystals in the microbatch system which belonged to the space group C2 and diffracted isotropically to approximately 2 A resolution.

Characterization of the binding interface between ubiquitin and class I human ubiquitin-conjugating enzyme 2b by multidimensional heteronuclear NMR spectroscopy in solution.

Ubiquitin-conjugating enzymes (Ubc) are involved in ubiquitination of proteins in the protein degradation pathway of eukaryotic cells. Ubc transfers the ubiquitin (Ub) molecules to target proteins by forming a thioester bond between their active site cysteine residue and the C-terminal glycine residue of ubiquitin. Here, we report on the NMR assignment and secondary structure of class I human ubiquitin-conjugating enzyme 2b (HsUbc2b). Chemical shift perturbation studies allowed us to map the contact area and binding interface between ubiquitin and HsUbc2b by1H-15N HSQC NMR spectroscopy. The serine mutant of the active site Cys88 of HsUbc2b was employed to obtain a relatively stable covalent ubiquitin complex of HsUbc2b(C88S). Changes in chemical shifts of amide protons and nitrogen atoms induced by the formation of the covalent complex were measured by preparing two segmentally labeled complexes with either ubiquitin or HsUbc2b(C88S)15N-labeled. In ubiquitin, the interaction is primarily sensed by the C-terminal segment Val70 - Gly76, and residues Lys48 and Gln49. The surface area on ubiquitin, as defined by these residues, overlaps partially with the presumed binding site with ubiquitin-activating enzyme (E1). In HsUbc2b, most of the affected residues cluster in the vicinity of the active site, namely, around the active site Cys88 itself, the second alpha-helix, and the flexible loop which connects helices alpha2 and alpha3 and which is adjacent to the active site. An additional site on HsUbc2b for a weak interaction with ubiquitin could be detected in a titration study where the two proteins were not covalently linked. This site is located on the backside of HsUbc2b opposite to the active site and is part of the beta-sheet. The covalent and non-covalent interaction sites are clearly separated on the HsUbc2b surface, while no such clear-cut segregation of the interaction area was observed on ubiquitin.

HMQC and HSQC experiments with water flip-back optimized for large proteins.

An HMQC experiment is proposed, dubbed FHMQC, where water flip-back is achieved by a single water-selective pulse preceding the basic HMQC pulse sequence. The scheme is demonstrated with a 15N,1H-HMQC spectrum of uniformly 15N/2H-labelled S. aureus DNA gyrase B with a molecular weight of 45 kDa for the unlabelled protein. The sensitivity of the experiment is improved compared to that of an FHSQC spectrum. It is further shown that the original FHSQC experiment can be shortened by the use of bipolar gradients. Relaxation times of different 15N magnetizations and coherences were measured. The new FHMQC scheme is implemented in 3D NOESY-15N-HMQC and 3D 15N-HMQC-NOESY-15N-HMQC pulse sequences which are demonstrated with a 24 kDa fragment of uniformly 15N/13C/2H-labelled S. aureus DNA gyrase B.

The three-dimensional high resolution structure of human interferon alpha-2a determined by heteronuclear NMR spectroscopy in solution.

The solution structure of recombinant human interferon alpha-2a (Roferon-A) has been determined by multidimensional heteronuclear NMR spectroscopy. The calculations using simulated annealing produced a family of 24 convergent structures which satisfy the experimental restraints comprising 1541 NOE-derived inter-proton distances, 187 dihedral restraints, 66 pairs of hydrogen bond restraints, and six upper and lower limits for two disulfide bridges. The fractional labeling of methyl groups allowed their direct and unambiguous stereospecific assignment which proved to be essential for obtaining a high resolution of the structures. A best fit superposition of residues 10 to 47, 50 to 101 and 111 to 157 gives an rms deviation of 0.62 A for the backbone heavy atoms and 1.39 A for all heavy atoms of these segments. The dominant feature of the structure is a cluster of five alpha-helices, four of which are arranged to form a left-handed helix bundle with an up-up-down-down topology and two over-hand connections. The interpretation of heteronuclear 15N-¿1H¿ NOE data shows the co-existence of flexible regions within an otherwise rigid framework of the protein. Four stretches of pronounced flexibility can be located: Cys1-Ser8, Gly44-Ala50, Ile100-Lys112, and Ser160-Glu165. Among the structurally related four-helical bundle cytokines, the structure of IFN alpha-2a is most similar to that of human interferon alpha-2b and murine interferon-beta. From this structural information and mutagenesis data, areas on the surface of the protein are identified which seem to be important in receptor interactions.

Crystal structures of cellular retinoic acid binding proteins I and II in complex with all-trans-retinoic acid and a synthetic retinoid.

BACKGROUND: Retinoic acid (RA) plays a fundamental role in diverse cellular activities. Cellular RA binding proteins (CRABPs) are thought to act by modulating the amount of RA available to nuclear RA receptors. CRABPs and cellular retinol-binding proteins (CRBPs) share a unique fold of two orthogonal beta-sheets that encapsulate their ligands. It has been suggested that a trio of residues are the prime determinants defining the high specificity of CRBPs and CRABPs for their physiological ligands. RESULTS: Bovine/murine CRABP I and human CRABP II have been crystallized in complex with their natural ligand, all-trans-RA. Human CRABP II has also been crystallized in complex with a synthetic retinoid, 'compound 19'. Their structures have been determined and refined at resolutions of 2.9 A, 1.8 A and 2.2 A, respectively. CONCLUSIONS: The retinoid-binding site in CRABPs differs significantly from that observed in CRBP. Structural changes in three juxtaposed areas of the protein create a new, displaced binding site for RA. The carboxylate of the ligand interacts with the expected trio of residues (Arg132, Tyr134 and Arg111; CRABP II numbering). The RA ligand is almost flat with the beta-ionone ring showing a significant deviation (-33 degrees) from a cis conformation relative to the isoprene tail. The edge atoms of the beta-ionone ring are accessible to solvent in a suitable orientation for presentation to metabolizing enzymes. The bulkier synthetic retinoid causes small conformational changes in the protein structure.

The formation of diselenide bridges in proteins by incorporation of selenocysteine residues: biosynthesis and characterization of (Se)2-thioredoxin.

A system was devised which allows the efficient substitution of cysteine residues in a protein by selenocysteine. It involves overexpression of the respective gene with the aid of the T7 promotor/polymerase system in a cysteine auxotrophic strain. The induction of the T7 polymerase formation was performed in cysteine-supplemented medium followed by wash-out of the cysteine and production of the desired gene product in the presence of selenocysteine. The system was applied to substitute the two cysteine residues in Escherichia coli thioredoxin. Analysis of the purified gene product by electrospray mass spectrometry and HPLC revealed that both cysteine residues were replaced in approximately 75-80% of the protein, only one cysteine residue was substituted in about 5-10%, and no substitution had taken place in 12-17% of the protein. The occurrence of diselenide, seleno-sulfur, and disulfide bridges in the purified gene product was revealed by ES/MS and chemical modification studies. The diselenide bridge represents an entity in protein structures which has hitherto not been described. The redox property of the selenocysteine variant of thioredoxin [(Se)2-thioredoxin] was found to be substantially different from that of thioredoxin. Only the latter could be reduced under native conditions in the presence of an excess of beta-mercaptoethanol. The oxidized (Se)2-thioredoxin was then separated from the selectively reduced and carboxymethylated protein by anion-exchange chromatography. The purity of the isolated (Se)2-thioredoxin was at least 92%.