The crystal structures of the copper enzyme phenylethylamine oxidase from the Gram-positive bacterium Arthrobacter globiformis (AGAO) have been determined and refined for three forms of the enzyme: the holoenzyme in its active form (at 2.2 A resolution), the holoenzyme in an inactive form (at 2.8 A resolution), and the apoenzyme (at 2.2 A resolution). The holoenzyme has a topaquinone (TPQ) cofactor formed from the apoenzyme by the post-translational modification of a tyrosine residue in the presence of Cu2+. Significant differences between the three forms of AGAO are limited to the active site. The polypeptide fold is closely similar to those of the amine oxidases from Escherichia coli [Parsons, M. R., et al. (1995) Structure 3, 1171-1184] and pea seedlings [Kumar, V., et al. (1996) Structure 4, 943-955]. In the active form of holo-AGAO, the active-site Cu atom is coordinated by three His residues and two water molecules in an approximately square-pyramidal arrangement. In the inactive form, the Cu atom is coordinated by the same three His residues and by the phenolic oxygen of the TPQ, the geometry being quasi-trigonal-pyramidal. There is evidence of disorder in the crystals of both forms of holo-AGAO. As a result, only the position of the aromatic group of the TPQ cofactor, but not its orientation about the Cbeta-Cgamma bond, is determined unequivocally. In apo-AGAO, electron density consistent with an unmodified Tyr occurs at a position close to that of the TPQ in the inactive holo-AGAO. This observation has implications for the biogenesis of TPQ. Two features which have not been described previously in amine oxidase structures are a channel from the molecular surface to the active site and a solvent-filled cavity at the major interface between the two subunits of the dimer.
The structure of the electron-transfer protein, plastocyanin (99 amino acids, one Cu atom, 10 500 Da) from poplar leaves, has been refined at 1.33 A resolution to a residual R=0.15. The space group is orthorhombic, P2~2~2~, a = 29.60 (1), b = 46.86 (3), c = 57.60 (3)A. The 14 303 reflections used in the refinement were obtained from a data set recorded on a four-circle diffractometer with radiation from a sealed fine-focus tube, combined with a data set measured on oscillation films exposed at the DESY synchrotron. The final model comprises 1442 (738 non-H) protein atoms, one Cu atom and 110 solvent molecules. Nine residues are described as disordered. The root-mean-square deviation from ideal bond lengths is 0.016 A and the root-mean-square difference between the positions of the C" atoms in this refined model and in the structure previously refined at 1.6 A resolution is 0.11 A. The effects of manual model adjustment, resolution, choice of standard values for geometrical parameters, inclusion of H atoms and inclusion of anomalousscattering corrections on the copper-site geometry have been explored. The final values of the Culigand bond lengths are: Cu--N(His37) 1.91, Cu--S(Cys84) 2.07, Cu--N(His87) 2.06, Cu--S(Met92) 2.82 A.
There is considerable structural homology between PSAO and ECAO. A combination of evidence from both structures indicates that the TPQ side chain is sufficiently flexible to permit the aromatic grouf to rotate about the Cbeta-Cgamma bond, and to move between bonding and non-bonding positions with respect to the Cu atom. Conformational flexibility is also required at the surface of the molecule to allow the substrates access to the active site, which is inaccessible to solvent, as expected for an enzyme that uses radical chemistry.
The structure of the proline-specific aminopeptidase (EC 3.4.11.9) from Escherichia coli has been solved and refined for crystals of the native enzyme at a 2.0-Å resolution, for a dipeptide-inhibited complex at 2.3-Å resolution, and for a low-pH inactive form at 2.7-Å resolution. The protein crystallizes as a tetramer, more correctly a dimer of dimers, at both high and low pH, consistent with observations from analytical ultracentrifuge studies that show that the protein is a tetramer under physiological conditions. The monomer folds into two domains. The active site, in the larger C-terminal domain, contains a dinuclear manganese center in which a bridging water molecule or hydroxide ion appears poised to act as the nucleophile in the attack on the scissile peptide bond of Xaa-Pro. The metal-binding residues are located in a single subunit, but the residues surrounding the active site are contributed by three subunits. The fold of the protein resembles that of creatine amidinohydrolase (creatinase, not a metalloenzyme). The C-terminal catalytic domain is also similar to the single-domain enzyme methionine aminopeptidase that has a dinuclear cobalt center.Proline-specific peptidases have been described in a wide variety of organisms and specifically cleave either the amide bond after a proline residue or the imide bond that precedes it (1). Proline aminopeptidases (EC 3.4.11.9) specifically release the N-terminal residue from a peptide where the penultimate residue is proline. These enzymes have significant sequence homology with (i) some other amino peptidases (e.g., methionine aminopeptidase, AMPM) and (ii) the Xaa-Pro dipeptidases, prolidases, that specifically cleave Xaa-Pro dipeptides. All these enzymes are activated in the presence of divalent metal ions, though the biologically active metal is not always certain. In vitro the prolyl peptidases are most active in the presence of Mn 2ϩ . Structural comparisons between AMPM and creatine amidinohydrolase (creatinase) and sequence comparisons between these proteins and aminopeptidase P (AMPP) and prolidase have suggested that the catalytic domains of all four enzymes have a common fold (2). This work presents the crystal structure of AMPP, the product of the pepP gene in Escherichia coli. The structures of a complex of AMPP with a dipeptide inhibitor and a low-pH inactive form are used to devise a plausible mechanism for peptide hydrolysis.
EXPERIMENTAL PROCEDURESOverexpression and Purification of AMPP. AMPP was originally isolated and characterized in E. coli (3) and was subsequently cloned and overexpressed (4). The details of the overexpression and purification of AMPP used in this work will be published elsewhere. Briefly, AMPP was overexpressed in the E. coli AN1459͞pPL670. Lysed cells were subject to (NH 4 ) 2 SO 4 precipitation at 4°C followed by centrifugation. The pellet was resuspended and applied to a DEAE-Fractogel column (Merck). The AMPP-containing fraction was then passed over a ceramic hydroxyapatite column (Bio-Rad). This simple purifi...
In 2012, preliminary guidelines were published addressing sample quality, data acquisition and reduction, presentation of scattering data and validation, and modelling for biomolecular small-angle scattering (SAS) experiments. Biomolecular SAS has since continued to grow and authors have increasingly adopted the preliminary guidelines. In parallel, integrative/hybrid determination of biomolecular structures is a rapidly growing field that is expanding the scope of structural biology. For SAS to contribute maximally to this field, it is essential to ensure open access to the information required for evaluation of the quality of SAS samples and data, as well as the validity of SAS-based structural models. To this end, the preliminary guidelines for data presentation in a publication are reviewed and updated, and the deposition of data and associated models in a public archive is recommended. These guidelines and recommendations have been prepared in consultation with the members of the International Union of Crystallography (IUCr) Small-Angle Scattering and Journals Commissions, the Worldwide Protein Data Bank (wwPDB) Small-Angle Scattering Validation Task Force and additional experts in the field.
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