http://www.biochemj.org Biochemical Journal - BJ ChemBio RSS Feed 0264-6021 1470-8728 Biochemical Journal http://www.biochemj.org/images/bj_Name.gif http://www.biochemj.org http://www.biochemj.org/bj/444/0219/bj4440219.htm NiRs (nitrite reductases) convert nitrite into NO in the denitrification process. RpNiR (Ralstonia pickettii NiR), a new type of dissimilatory Cu-containing NiR with a C-terminal haem c domain from R. pickettii, has been cloned, overexpressed in Escherichia coli and purified to homogeneity. The enzyme has a subunit molecular mass of 50515 Da, consistent with sequence data showing homology to the well-studied two-domain Cu NiRs, but with an attached C-terminal haem c domain. Gel filtration and combined SEC (size-exclusion chromatography)-SAXS (small angle X-ray scattering) analysis shows the protein to be trimeric. The metal content of RpNiR is consistent with each monomer having a single haem c group and the two Cu sites being metallated by Cu²⁺ ions. The absorption spectrum of the oxidized as-isolated recombinant enzyme is dominated by the haem c. X-band EPR spectra have clear features arising from both type 1 Cu and type 2 Cu centres in addition to those of low-spin ferric haem. The requirements for activity and low apparent K_m for nitrite are similar to other CuNiRs (Cu-centre NiRs). However, EPR and direct binding measurements of nitrite show that oxidized RpNiR binds nitrite very weakly, suggesting that substrate binds to the reduced type 2 Cu site during turnover. Analysis of SEC-SAXS data suggests that the haem c domains in RpNiR form extensions into the solvent, conferring a high degree of conformational flexibility in solution. SAXS data yield R_g (gyration radius) and D_max (maximum particle diameter) values of 43.4 Å (1 Å=0.1 nm) and 154 Å compared with 28 Å and 80 Å found for the two-domain CuNiR of Alcaligenes xylosoxidans.

]]> Cong Han, Gareth S. A. Wright, Karl Fisher, Stephen E. J. Rigby, Robert R. Eady and S. Samar Hasnain 2012-06-01 doi:10.1042/BJ20111623 c dissimilatory nitrite reductase from Ralstonia pickettii]]> Portland Press Ltd. 2012-06-01 http://www.biochemj.org/bj/444/0269/bj4440269.htm Natural and synthetic carbamates act as pseudo-irreversible inhibitors of AChE (acetylcholinesterase) as well as BChE (butyrylcholinesterase), two enzymes involved in neuronal function as well as in the development and progression of AD (Alzheimer's disease). The AChE mode of action is characterized by a rapid carbamoylation of the active-site Ser²⁰⁰ with release of a leaving group followed by a slow regeneration of enzyme action due to subsequent decarbamoylation. The experimental AD therapeutic bisnorcymserine, a synthetic carbamate, shows an interesting activity and selectivity for BChE, and its clinical development is currently being pursued. We undertook detailed kinetic studies on the activity of the carbamate bisnorcymserine with Tc (Torpedo californica) AChE and, on the basis of the results, crystallized the complex between TcAChE and bisnorcymserine. The X-ray crystal structure showed only the leaving group, bisnoreseroline, trapped at the bottom of the aromatic enzyme gorge. Specifically, bisnoreseroline interacts in a non-covalent way with Ser²⁰⁰ and His⁴⁴⁰, disrupting the existing interactions within the catalytic triad, and it stacks with Trp⁸⁴ at the bottom of the gorge, giving rise to an unprecedented hydrogen-bonding contact. These interactions point to a dominant reversible inhibition mechanism attributable to the leaving group, bisnoreseroline, as revealed by kinetic analysis.

]]> Cecilia Bartolucci, Jure Stojan, Qian‑sheng Yu, Nigel H. Greig and Doriano Lamba 2012-06-01 doi:10.1042/BJ20111675 Torpedo californica acetylcholinesterase inhibition by bisnorcymserine and crystal structure of the complex with its leaving group]]> Portland Press Ltd. 2012-06-01