Haem degradation in animals and plants.

Two enzyme systems have evolved for the reduction of linear tetrapyrroles: one family, found in plants, algae and cyanobacteria, uses ferredoxin and catalyses the reduction of the terminal pyrrole rings (A and D) and one of the vinyl side chains to form various light-harvesting and light-sensing chromophores. The other group (biliverdin reductases A and B) utilize NAD(P)H and catalyse reduction at C10 (hydride addition) to form the 'bile' pigments bilirubin-IX alpha and bilirubin-IX.

Enzymes: nature's nanomachines. Royal Irish Academy Medal Lecture.

The development of enzyme kinetics, protein crystallography and NMR studies allows enzyme-catalysed reactions to be described in terms of mechanistic chemistry, albeit applied to relatively enormous molecules. These nanomachines, which so inspired Drexler's "Engines of Creation," have been working in biological systems for over three billion years and represent a useful knowledge base for our further understanding of mechanistic biology. They also provide a tantalizing glimpse into what may be the basis for novel technologies with industrial applications for the twenty-first century.

Structure of human biliverdin IXbeta reductase, an early fetal bilirubin IXbeta producing enzyme.

Biliverdin IXbeta reductase (BVR-B) catalyzes the pyridine nucleotide-dependent production of bilirubin-IXbeta, the major heme catabolite during early fetal development. BVR-B displays a preference for biliverdin isomers without propionates straddling the C10 position, in contrast to biliverdin IXalpha reductase (BVR-A), the major form of BVR in adult human liver. In addition to its tetrapyrrole clearance role in the fetus, BVR-B has flavin and ferric reductase activities in the adult. We have solved the structure of human BVR-B in complex with NADP+ at 1.15 A resolution. Human BVR-B is a monomer displaying an alpha/beta dinucleotide binding fold. The structures of ternary complexes with mesobiliverdin IValpha, biliverdin IXalpha, FMN and lumichrome show that human BVR-B has a single substrate binding site, to which substrates and inhibitors bind primarily through hydrophobic interactions, explaining its broad specificity. The reducible atom of both biliverdin and flavin substrates lies above the reactive C4 of the cofactor, an appropriate position for direct hydride transfer. BVR-B discriminates against the biliverdin IXalpha isomer through steric hindrance at the bilatriene side chain binding pockets. The structure also explains the enzyme's preference for NADP(H) and its B-face stereospecificity.

Studies on the specificity of the tetrapyrrole substrate for human biliverdin-IXalpha reductase and biliverdin-IXbeta reductase. Structure-activity relationships define models for both active sites.

A comparison of the initial rate kinetics for human biliverdin-IXalpha reductase and biliverdin-IXbeta reductase with a series of synthetic biliverdins with propionate side chains "moving" from a bridging position across the central methene bridge (alpha isomers) to a "gamma-configuration" reveals characteristic behavior that allows us to propose distinct models for the two active sites. For human biliverdin-IXalpha reductase, as previously discussed for the rat and ox enzymes, it appears that at least one "bridging propionate" is necessary for optimal binding and catalytic activity, whereas two are preferred. All other configurations studied were substrates for human biliverdin-IXalpha reductase, albeit poor ones. In the case of mesobiliverdin-XIIIalpha, extending the propionate side chains to hexanoate resulted in a significant loss of activity, whereas the butyrate derivative retained high activity. For human biliverdin-IXalpha reductase, we suggest that a pair of positively charged side chains play a key role in optimally binding the IXalpha isomers. In the case of human biliverdin-IXbeta reductase, the enzyme cannot tolerate even one propionate in the bridging position, suggesting that two negatively charged residues on the enzyme surface may preclude productive binding in this case. The flavin reductase activity of biliverdin-IXbeta reductase is potently inhibited by mesobiliverdin-XIIIalpha and protohemin, which is consistent with the hypothesis that the tetrapyrrole and flavin substrate bind at a common site.

Initial-rate kinetics of the flavin reductase reaction catalysed by human biliverdin-IXbeta reductase (BVR-B).

The initial-rate kinetics of the flavin reductase reaction catalysed by biliverdin-IXbeta reductase at pH 7.5 are consistent with a rapid-equilibrium ordered mechanism, with the pyridine nucleotide binding first. NADPH binding to the free enzyme was characterized using stopped-flow fluorescence quenching, and a K(d) of 15.8 microM was calculated. Equilibrium fluorescence quenching experiments indicated a K(d) of 0.55 microM, suggesting that an enzyme-NADPH encounter complex (K(d) 15.8 microM) isomerizes to a more stable 'nucleotide-induced' conformation. The enzyme was shown to catalyse the reduction of FMN, FAD and riboflavin, with K(m) values of 52 microM, 125 microM and 53 microM, respectively. Lumichrome was shown to be a competitive inhibitor against FMN, with a K(i) of 76 microM, indicating that interactions with the isoalloxazine ring are probably sufficient for binding. During initial experiments it was observed that both the flavin reductase and biliverdin reductase activities of the enzyme exhibit a sharp optimum at pH 5 in citrate buffer. An initial-rate study indicated that the enzyme obeys a steady-state ordered mechanism in this buffer. The initial-rate kinetics in sodium acetate at pH 5 are consistent with a rapid-equilibrium ordered mechanism, indicating that citrate may directly affect the enzyme's behaviour at pH 5. Mesobiliverdin XIIIalpha, a synthetic biliverdin which binds to flavin reductase but does not act as a substrate for the enzyme, exhibits competitive kinetics with FMN (K(i) 0.59 microM) and mixed-inhibition kinetics with NADPH. This is consistent with a single pyridine nucleotide site and competition by FMN and biliverdin for a second site. Interestingly, flavin reductase/biliverdin-IXbeta reductase has also been shown to exhibit ferric reductase activity, with an apparent K(m) of 2.5 microM for the ferric iron. The ferric reductase reaction requires NAD(P)H and FMN. This activity is intriguing, as haem cleavage in the foetus produces non-alpha isomers of biliverdin and ferric iron, both of which are substrates for flavin reductase/biliverdin-IXbeta reductase.

The three-dimensional structure of a class-Pi glutathione S-transferase complexed with glutathione: the active-site hydration provides insights into the reaction mechanism.

The structure of mouse liver glutathione S-transferase P1-1 complexed with its substrate glutathione (GSH) has been determined by X-ray diffraction analysis. No conformational changes in the glutathione moiety or in the protein, other than small adjustments of some side chains, are observed when compared with glutathione adduct complexes. Our structure confirms that the role of Tyr-7 is to stabilize the thiolate by hydrogen bonding and to position it in the right orientation. A comparison of the enzyme-GSH structure reported here with previously described structures reveals rearrangements in a well-defined network of water molecules in the active site. One of these water molecules (W0), identified in the unliganded enzyme (carboxymethylated at Cys-47), is displaced by the binding of GSH, and a further water molecule (W4) is displaced following the binding of the electrophilic substrate and the formation of the glutathione conjugate. The possibility that one of these water molecules participates in the proton abstraction from the glutathione thiol is discussed.

The three-dimensional structure of Cys-47-modified mouse liver glutathione S-transferase P1-1. Carboxymethylation dramatically decreases the affinity for glutathione and is associated with a loss of electron density in the alphaB-310B region.

The three-dimensional structure of mouse liver glutathione S-transferase P1-1 carboxymethylated at Cys-47 and its complex with S-(p-nitrobenzyl)glutathione have been determined by x-ray diffraction analysis. The structure of the modified enzyme described here is the first structural report for a Pi class glutathione S-transferase with no glutathione, glutathione S-conjugate, or inhibitor bound. It shows that part of the active site area, which includes helix alphaB and helix 310B, is disordered. However, the environment of Tyr-7, an essential residue for the catalytic reaction, remains unchanged. The position of the sulfur atom of glutathione is occupied in the ligand-free enzyme by a water molecule that is at H-bond distance from Tyr-7. We do not find any structural evidence for a tyrosinate form, and therefore our results suggest that Tyr-7 is not acting as a general base abstracting the proton from the thiol group of glutathione. The binding of the inhibitor S-(p-nitrobenzyl)-glutathione to the carboxymethylated enzyme results in a partial restructuring of the disordered area. The modification of Cys-47 sterically hinders structural organization of this region, and although it does not prevent glutathione binding, it significantly reduces the affinity. A detailed kinetic study of the modified enzyme indicates that the carboxymethylation increases the Km for glutathione by 3 orders of magnitude, although the enzyme can function efficiently under saturating conditions.

On the reaction mechanism of class Pi glutathione S-transferase.

Theoretical calculations were performed to examine the ionization of the phenolic group of Tyr7 and the thiol group of glutathione in aqueous solution and in the protein class-pi glutathione S-transferase (GST-Pi). Three model systems were considered for simulations in the protein environments the free enzyme, the complex between glutathione and the enzyme, and the complex between 1-chloro-2.4-dinitrobenzene, glutathione, and the enzyme. The structures derived from Molecular Dynamics simulations were compared with the crystallographic data available for the complex between the inhibitor S-(p-nitrobenzyl)glutathione and GST-Pi, the glutathione-bound form of GST-Pi, and the free enzyme carboxymethylated in Cys47. Free-energy perturbation techniques were used to determine the thermodynamics quantities for ionization of the phenol and thiol groups. The functional implications of Tyr7 in the activation of the glutathione thiol group are discussed in the light of present results, which in agreement with previous studies suggest that Tyr7 in un-ionized form contributes to the catalytic process of glutathione S-transferase, the thiolate anion being stabilized by hydrogen bond with Tyr7 and by interactions with hydrating water molecules.

Cloning and overexpression of rat kidney biliverdin IX alpha reductase as a fusion protein with glutathione S-transferase: stereochemistry of NADH oxidation and evidence that the presence of the glutathione S-transferase domain does not effect BVR-A activity.

Native biliverdin IX alpha reductase (BVR-A) is a monomer of molecular mass 34 kDa. We have developed an expression vector that allows the isolation of 40 mg of a glutathione S-transferase (GST)-BVR-A fusion protein from 1 litre of culture. The fusion protein (60 kDa) behaves as a dimer on gel filtration (120 kDa), so that we have artificially created a BVR-A dimer. The recombinant rat kidney enzyme exhibits pre-steady-state 'burst' kinetics that show a pH dependence similar to that already described for ox kidney BVR-A. Similar behaviour was obtained in the presence and absence of the GST domain both for the burst kinetics and during initial-rate studies in the presence and absence of albumin. The stereospecificity of the BVR-A-catalysed oxidation of [4-3H]NADH, labelled at the A and B faces, was shown to occur exclusively via the B face.

Evidence that biliverdin-IX beta reductase and flavin reductase are identical.

A search of the database shows that human biliverdin-IX beta reductase and flavin reductase are identical. We have isolated flavin reductase from bovine erythrocytes and show that the activity co-elutes with biliverdin-IX beta reductase. Preparations of the enzyme that are electrophoretically homogeneous exhibit both flavin reductase and biliverdin-IX beta reductase activities; however, they are not capable of catalysing the reduction of biliverdin-IX alpha. Although there is little obvious sequence identity between biliverdin-IX alpha reductase (BVR-A) and biliverdin-IX beta reductase (BVR-B), they do show weak immunological cross-reactivity. Both enzymes bind to 2',5'-ADP-Sepharose.

Microalbuminuria in inflammatory bowel disease.

Microalbuminuria independently predicts the development of nephropathy and increased cardiovascular morbidity and mortality in diabetic patients, but it may be an indicator of the acute phase response. This study examined microalbuminuria as a marker of the acute phase response in patients with inflammatory bowel disease and correlated it with the disease activity in 95 patients with inflammatory bowel disease (ulcerative colitis (n = 52), Crohn's disease (n = 43)) determined by the simple index of Harvey and Bradshaw. Fifty patients were in complete clinical remission and 45 patients had active disease. Microalbuminuria was detected in all patients with inflammatory bowel disease (147 (17) v 18 (2) microgram/min, inflammatory bowel disease v controls mean (SEM), p < 0.007). Patients with active inflammatory bowel disease had higher concentrations of microalbuminuria compared with patients in remission (206 (19) v 65 (8) microgram/min, mean (SEM), p < 0.0001). Eight patients with active inflammatory bowel disease who were sequentially followed up with measurements of microalbuminuria had significantly lower values, when the disease was inactive (active inflammatory bowel disease 192 (44) v inactive inflammatory bowel disease 64 (14) microgram/min, p < 0.03). There was a significant correlation with the simple index of Harvey and Bradshaw (r = 0.818, p < 0.0001). Microalbuminuria values were significantly lower in inflammatory bowel disease patients in remission, maintained with olsalazine compared with those patients maintained with mesalazine and salazopyrine, but no significant difference was seen in values of microalbuminuria in active inflammatory bowel disease patients receiving different salicylates. This study also measured serum amyloid-A as an indicator of the acute phase response in the same patients. Serum amyloid-A was significantly increased in active disease compared with inactive disease (151 (43) v 33 (7) or controls 11 (2) micrograms/ml, p < 0.05). In conclusion microalbuminuria is present in abnormal amounts in all patients with active inflammatory bowel disease, and values fall when the disease is quiescent. Microalbuminuria is probably a consequence of an acute phase response and provides a simple, rapid, and inexpensive test, which has the potential to monitor inflammatory bowel disease activity and response to treatment.

Molecular structure at 1.8 A of mouse liver class pi glutathione S-transferase complexed with S-(p-nitrobenzyl)glutathione and other inhibitors.

The three-dimensional crystal structure of pi class glutathione S-transferase YfYf from mouse liver complexed with the inhibitor S-(p-nitrobenzyl)glutathione has been determined at 1.8 A resolution by X-ray diffraction. In addition two complexes with glutathione sulphonic acid and S-hexylglutathione have been determined at resolutions of 1.9 and 2.2 A, respectively. The high resolution of the S-(p-nitrobenzyl)glutathione complex allows a detailed analysis of the active site including the hydrophobic (H-) subsite. The nitrobenzyl moiety occupies a hydrophobic pocket with its aromatic ring sandwiched between Phe8 and the hydroxyl group of Tyr108. An insertion of two residues Gly41 and Leu42, with respect to the pig enzyme, splits helix alpha B into an alpha-helix and a 3(10) helix. Water bridges between carbonyl oxygen atoms of the alpha-helix at its C terminus and the amide NH groups of the 3(10) helix at its N terminus provide structural continuity between these two secondary elements. Tyr7 appears to be the only residue close to the sulphur atom of glutathione, while three conserved water molecules lie in the surrounding area in all complexes. The enzyme mechanism is discussed on the basis of the structural analysis.

Effect of lead acetate and carbon particles on the expression of glutathione S-transferase YfYf in rat liver.

Administration of intracardiac lead acetate produces a complex response in glutathione S-transferase (GST) YfYf expression in rat liver. The earliest response, an elevation of GST expression in Kupffer cells, can be mimicked by administering a suspension of carbon particles. The second effect of lead acetate administration is a marked elevation of GST YfYf in some but not all hepatocytes (the 'patchy' response). This effect is most marked 48-76 h after administration of a single dose of lead acetate and is easily detected by immunoblotting. Dexamethasone down-regulates the lead response in hepatocytes.

Inactivation of mouse liver glutathione S-transferase YfYf (Pi class) by ethacrynic acid and 5,5'-dithiobis-(2-nitrobenzoic acid).

Mouse liver glutathione S-transferase YfYf (Pi class) reacts with [14C]ethacrynic acid to form a covalent adduct with a stoichiometry of 1 mol per mol of subunit. Proteolytic digestion of the enzyme-[14C]ethacrynic acid adduct with V8 protease produced an 11 kDa fragment containing radioactivity. Sequencing revealed this to be an N-terminal peptide (minus the first 15 residues, terminating at Glu-112) which contains only one cysteine residue (Cys-47). This is tentatively identified as the site of ethacrynic attachment. Kinetic studies reveal that glutathione S-conjugates protect against inactivation by ethacrynic acid, but the level of protection is not consistent with their potency as product inhibitors. A model is proposed in which glutathione S-conjugates and ethacrynic acid compete for the free enzyme, and a second molecule of ethacrynic acid reacts covalently with the enzyme-ethacrynic acid complex. The native protein contains one thiol reactive with 5,5'-dithiobis-(2-nitrobenzoic acid) at neutral pH. The resultant mixed disulphide, like the ethacrynic acid adduct, is inactive, but treatment with cyanide (which incorporates on a mol for mol basis) restores activity to 35% of that of the native enzyme.