Fraser E. Dodd

The substrate-binding site in Cu nitrite reductase and its similarity to Zn carbonic anhydrase.

Here we investigate the structure of the two types of copper site in nitrite reductase from Alcaligenes xylosoxidans, the molecular organisation of the enzyme when the type-2 copper is absent, and its mode of substrate binding. X-ray absorption studies provide evidence for a fourth ligand at the type-2 Cu, that substrate binds to this site and indicates that this binding does not change the type-1 Cu centre. The substrate replaces a putative water ligand and is accommodated by a lengthening of the Cu–histidine bond by approximately 0.08 Å. Modelling suggests a similarity between this unusual type-2 Cu site and the Zn site in carbonic anhydrase and that nitrite is anchored by hydrogen bonds to an unligated histidine present in the type-2 Cu cavity.

Crystal structures of the Met148Leu and Ser86Asp mutants of rusticyanin from Thiobacillus ferrooxidans: Insights into the structural relationship with the cupredoxins and the multi copper proteins

The crystal structures of the Met148Leu and Ser86Asp mutants of rusticyanin are presented at 1.82 and 1.65 A resolution, respectively. Both of these structures have two molecules in the asymmetric unit compared to the one present in the crystal form of the native protein. This provides an opportunity to investigate intramolecular electron transfer pathways in rusticyanin. The redox potential of the Met148Leu mutant ( approximately 800 mV) is elevated compared to that of the native protein ( approximately 670 mV at pH 3.2) while that of the Ser86Asp mutant ( approximately 623 mV at pH 3.2) is decreased. The effect of the Ser86Asp mutation on the hydrogen bonding near the type 1 Cu site is discussed and hence its role in determining acid stability is examined. The type 1 Cu site of Met148Leu mimics the structural and biochemical characteristics of those found in domain II of ceruloplasmin and fungal laccase. Moreover, the native rusticyanins cupredoxin core and the type 1 Cu site closely resemble those found in ascorbate oxidase and nitrite reductase. Structure based phylogenetic trees have been re-examined in view of the additional structural data on rusticyanin and fungal laccase. We confirm that rusticyanin is in the same class as nitrite reductase domain 2, laccase domain 3 and ceruloplasmin domains 2, 4 and 6.

X-ray structure of a blue copper nitrite reductase at high pH and in copper-free form at 1.9 Å resolution

Copper-containing nitrite reductases possess a trimeric structure where the catalytic Cu site, located at the monomer-monomer interface, resembles the catalytic sites of a number of Zn enzymes. Nitrite reductase from Alcaligenes xylosoxidans has optimum activity at pH 5.2 which decreases to a negligible level at pH 8. The structure of this nitrite reductase has previously been determined at pH 4.6. It has now been crystallized under new conditions at pH 8.5. Its crystallographic structure provides a structural explanation for the greatly reduced activity of the enzyme at high pH. Characterization of overexpressed protein in solution by EXAFS suggested that the protein lacked Cu in the catalytic type 2 Cu site and that the site was most probably occupied by Zn. Using the anomalous signals from Cu and Zn, the crystal structure revealed that the expressed protein was devoid of Cu in the catalytic site and that only a trace amount (<10%) of Zn was present at this site in the crystal. Despite the close structural similarity of the catalytic site to a number of Zn enzymes, these data suggest that Zn, if it binds at the catalytic copper site, binds weakly in nitrite reductase.

Structures of oxidized and reduced azurin II from Alcaligenes xylosoxidans at 1.75 Å resolution

Crystallographic structures of oxidized and reduced forms of azurin II are reported at 1.75 A resolution. Data were collected using one crystal in each case and by translating the crystal after each oscillation range to minimize photoreduction. Very small differences are observed at the Cu site upon reduction and these cannot be determined with confidence at current resolution. A comparison with the three-dimensional EXAFS reveals a good correspondence for all the ligand distances except for Cu-His46, where a larger deviation of approximately 0.12-0.18 A is observed, indicating that this ligand is more tightly restrained in the crystallographic refinement at the current resolution.

Ab initio phasing using molecular envelope from solution X-ray scattering.

Solving the phase problem is the crucial and quite often the most difficult and time-consuming step in crystallographic structure determination. The traditional methods of isomorphous replacement (MIR or SIR) and molecular replacement require the availability of an isomorphous heavy-atom derivative or the structure of a homologous protein, respectively. Here, a method is presented which utilizes the low-resolution molecular shape determined from solution X-ray scattering data for the molecular search. The molecular shape of a protein is an important structural property and can be determined directly by the small-angle scattering technique. The idea of locating this molecular shape in the crystallographic unit cell has been tested with experimental diffraction data from nitrite reductase (NiR). The conventional Patterson search proved to be unsuccessful, as the intra-envelope vectors are uniformly distributed and do not match those of intra-molecular (atom-to-atom) vectors. A direct real-space search for orientation and translation was then performed. A self-rotation function using 2.8 A crystallographic data yielded the polar angles of the non-crystallographic threefold axis. Knowledge of the orientation of this axis reduces the potential six-dimensional search to four (Eulerian angle gamma and three translational parameters). The direct four-dimensional search within the unit cell produced a clear solution. The electron-density map based on this solution agrees well with the known structure, and the phase error calculated from the map was 61 degrees within 20 A resolution. It is anticipated that the low-resolution envelope can be used as a starting model for phase extension by the maximum-entropy and density-modification method.

Structure Solution of Azurin II from Alcaligenes xylosoxidans using the Laue Method: Possibility of Studying In Situ Redox Changes using X-rays.

We have recently demonstrated that X-rays can be used for changing the redox states of the metal centre in metalloproteins [Murphy et al. (1995). J. Synchrotron Rad. 2, 64-69]. The possibility of using the Laue method for studying the structural changes associated with such X-ray-induced reactions is explored by applying the method to the structure determination of a new azurin (hereafter referred to as azurin II) from the denitrifying bacterium Alcaligenes xylosoxidans. Laue X-ray diffraction data of azurin II were collected at station 9.7 of the SRS Daresbury. Three diffraction patterns were recorded on film packs at three different crystal orientations. The data were processed using the Daresbury Laue Software Suite to give 2224 independent single reflections (R(merge) = 0.136) in the wavelength range 0.36-1.40 A. The data completeness was 44% at 2.55 A resolution. Phase determination for the data was undertaken using the molecular-replacement method; the top peak was chosen in both the rotation function and the subsequent translation function. This solution agreed well with the molecular-replacement solution achieved independently using monochromatic data. The electron-density map showed reasonably good agreement with the model and the copper site was readily recognizable as it had the highest density. To see if the electron-density map could be improved, ;the doublets in the diffraction data were then deconvoluted. This added 26% data in the region infinity-2d(min) resulting in an improvement in the data completeness to 50% and thus in improved continuity of the electron-density map. The quality of these maps is discussed from the point of view of the suitability of this approach for studying redox-induced structural changes.

Crystallographic Structures of Nitrite Reductase and its Substrate Bound Complex

Dissimilatory nitrite reductase (NiR) is a key enzyme in the anaerobic respiratory pathway of denitrifying bacteria where nitrate is sequentially reduced to the gaseous products NO, N2O or N2, leading to a significant loss of fixed nitrogen from the terrestrial environment (Payne, 1985). The NiR from Alcaligenes xylosoxidans (AxNiR) (Abraham et al., 1993) belongs to the group of NiRs which utilise copper at the redox active centres. All Cu NiRs isolated so far have a strong band near 600nm arising from a (Cys)S → Cu (II) charge transfer which is characteristic of a type 1 Cu centre. The ratio of intensity of this band to a second charge transfer absorption band at ∼460nm determines whether a Cu NiR is blue or green in colour (Han et al., 1993). AxNiR belongs to the subset of Cu-NiRs which are blue in colour and are thought to have azurin as the electron partner.

Structural changes at the copper centre of Azurin in an oxidation-reduction process: an integrated approach combining crystallography and EXAFS

of Azurin in an oxidation-reduction process: an integrated approach combining crystallography and EXAFS. F.E. Dodd[1], K.-C. Cheung[1,2], R.W. Strange[1], Z.H.L. Abraham[3], R.R. Eady[3] and S.S. Hasnain[1] 1.Synchrotron Radiation Department, CLRC Daresbury Laboratory, Warrington, WA4 4AD, UK. 2 Faculty of Applied Sciences, De Montfort University, Leicester, LE1 9BH, UK. 3 Nitrogen Fixation Laboratory, John Innes Centre, Colney, Norwich, NR4 7UH, UK.