Identification of the prion protein allotypes which accumulate in the brain of sporadic and familial Creutzfeldt-Jakob disease patients.

A characteristic feature of Creutzfeldt-Jakob disease (CJD) is the accumulation in the brain of the amyloid protease-resistant protein PrPres. PrPres derives from a host-encoded, protease-sensitive isoform, PrPsen. Mutations of this protein are linked to familial variants of the disease, and the presence of a methionine or valine residue at the polymorphic position 129 may be critical in sporadic CJD cases. We found that in the brain of patients heterozygous for the mutation in which isoleucine is substituted for valine at codon 210 (Val21Olle), the PrPres is formed by both the wild-type and mutant PrPsen. We also found that in a sporadic CJD patient, who was heterozygous (Met/Val) at position 129, PrPres is also formed by both allotypes. These data associate transmissible spongiform encephalopathies with other amyloidosis, although the nature of the transmissible agent remains unsettled.

N-terminal arm exchange is observed in the 2.15 A crystal structure of oxidized nitrite reductase from Pseudomonas aeruginosa.

BACKGROUND: Nitrite reductase from Pseudomonas aeruginosa (NiR-Pa) is a dimer consisting of two identical 60 kDa subunits, each of which contains one c and one d1 heme group. This enzyme, a soluble component of the electron-transfer chain that uses nitrate as a source of energy, can be induced by the addition of nitrate to the bacterial growth medium. NiR-Pa catalyzes the reduction of nitrite (NO2-) to nitric oxide (NO); in vitro, both cytochrome c551 and azurin are efficient electron donors in this reaction. NiR is a key denitrification enzyme, which controls the rate of the production of toxic nitric oxide (NO) and ultimately regulates the release of NO into the atmosphere. RESULTS: The structure of the orthorhombic form (P2(1)2(1)2) of oxidized NiR-Pa was solved at 2.15 A resolution, using molecular replacement with the coordinates of the NiR from Thiosphaera pantotropha (NiR-Tp) as the starting model. Although the d1-heme domains are almost identical in both enzyme structures, the c domain of NiR-Pa is more like the classical class I cytochrome-c fold because it has His51 and Met88 as heme ligands, instead of His17 and His69 present in NiR-Tp. In addition, the methionine-bearing loop, which was displaced by His17 of the NiR-Tp N-terminal segment, is back to normal in our structure. The N-terminal residues (5/6-30) of NiR-Pa and NiR-Tp have little sequence identity. In Nir-Pa, this N-terminal segment of one monomer crosses the dimer interface and wraps itself around the other monomer. Tyr10 of this segment is hydrogen bonded to an hydroxide ion--the sixth ligand of the d1-heme Fe, whereas the equivalent residue in NiR-Tp, Tyr25, is directly bound to the Fe. CONCLUSIONS: Two ligands of hemes c and d1 differ between the two known NiR structures, which accounts for the fact that they have quite different spectroscopic and kinetic features. The unexpected domain-crossing by the N-terminal segment of NiR-Pa is comparable to that of 'domain swapping' or 'arm exchange' previously observed in other systems and may explain the observed cooperativity between monomers of dimeric NiR-Pa. In spite of having similar sequence and fold, the different kinetic behaviour and the spectral features of NiR-Pa and NiR-Tp are tuned by the N-terminal stretch of residues. A further example of this may come from another NiR, from Pseudomonas stutzeri, which has an N terminus very different from that of the two above mentioned NiRs.

Crystallization and preliminary X-ray analysis of a new crystal form of nitrite reductase from Pseudomonas aeruginosa.

Nitrite reductase from Pseudomonas aeruginosa (EC 1.9.3.2), a redox enzyme synthesized by the bacterium grown in the presence of nitrate, is a soluble dimer of two identical subunits of 60 kDa, each containing one c and one d1 haem as prosthetic groups. A new crystal from of the Ps. aeruginosa nitrite reductase in the oxidized state, suitable for X-ray structure determination, has been obtained by vapour diffusion at 20 degrees C, in the presence of 10% polyethylene glycol 4000, 50 mM Tris-HCl (pH 8.7), 400 mM NaCl and at a protein concentration of 14 mg/ml. The crystals are dark green elongated tetragonal prisms of dimensions 1.5 mm x 0.2 mm x 0.2 mm for the largest ones. These crystals are tetragonal with space group P4(1(3))2(1)2 and cell dimensions a = b = 128.2 A, c = 172.6 A. They diffract at least up to 2.8 A. Assuming a dimer in the asymmetric unit, the VM value is 2.95 A3/Da (58% of solvent).

Nitrite reductase from Pseudomonas aeruginosa: sequence of the gene and the protein.

The gene coding for nitrite reductase of Pseudomonas aeruginosa has been cloned and its sequence determined. The coding region is 1707 bp long and contains information for a polypeptide chain of 568 amino acids. The sequence of the mature protein has been confirmed independently by extensive amino acid sequencing. The amino-terminus of the mature protein is located at Lys-26; the preceding 25 residue long extension shows the features typical of signal peptides. Therefore the enzyme is probably secreted into the periplasmic space. The mature protein is made of 543 amino acid residues and has a molecular mass of 60,204 Da. The c-heme-binding domain, which contains the only two Cys of the molecule, is located at the amino-terminal region. Analysis of the protein sequence in terms of hydrophobicity profile gives results consistent with the fact that the enzyme is fully water soluble and not membrane bound; the most hydrophilic region appears to correspond to the c-heme domain. Secondary structure predictions are in general agreement with previous analysis of circular dichroic data.

Reaction of the Hansenula anomala flavocytochrome b2 and cytochrome b2 core with inorganic outer sphere redox compounds.

The oxidation of reduced cytochrome b2 core and flavocytochrome b2 by three inorganic outer sphere compounds, Fe(CN)6(3-), Co(phen)3(3+) and Mn(CyDTA) (H2O)-, has been studied by stopped-flow. The reaction with Fe(CN)6(3-) is very rapid; the second order rate constants at 10 degrees C (pH 7) and I = 0.02 M are k = 1 x 10(8) M-1 s-1 and 1 x 10(7) M-1 s-1 for cytochrome b2 core and flavocytochrome b2, respectively. The reaction between cytochrome b2 core and Co(phen)3(3+), too fast at pH 7.0, has been characterized at 10 degrees C and pH 4.0; the second order rate constant is k = 2 x 10(7) M-1 s-1 and becomes 4 x 10(8) M-1 s-1 at pH 6.5. The reaction between flavocytochrome b2 and Co(phen)3(3+) has a second order rate constant k = 2 x 10(7) M-1 s-1 at pH 7.0, 10 degrees C. The oxidation of both proteins by Mn(CyDTA)(H2O)- is characterized by a second order rate constant k = 2.8 x 10(6) M-1 s-1 and 2.3 x 10(5) M-1 s-1 for cytochrome b2 core and flavocytochrome b2, respectively, at pH 7.0 and 10 degrees C. The reactivity of the b2 heme towards the outer sphere oxidants is higher than that reported for heme c in bacterial and eukaryotic cytochrome c. The larger delta E and the larger accessibility of the b2 heme can account for this result. The flavodehydrogenase domain seems to modulate the electron transfer also to these inorganic compounds, as found previously in the case of macromolecular electron acceptors.

Pseudomonas aeruginosa nitrite reductase (or cytochrome oxidase): an overview.

The biochemistry and molecular biology of nitrite reductase, a key enzyme in the dissimilatory denitrification pathway of Ps aeruginosa which reduces nitrite to NO, is reviewed in this paper. The enzyme is a non-covalent homodimer, each subunit containing one heme c and one heme d1. The reaction mechanisms of nitrite and oxygen reduction are discussed in detail, as well as the interaction of the enzyme with its macromolecular substrates, azurin and cytochrome c551. Special attention is paid to new structural information, such as the chemistry of the d1 prosthetic group and the primary sequence of the gene and the protein. Finally, results on the expression both in Ps aeruginosa and in heterologous systems are presented.

The nitrite reductase gene of Pseudomonas aeruginosa: effect of growth conditions on the expression and construction of a mutant by gene disruption.

The expression of nitrite reductase has been tested in a wild-type strain of Pseudomonas aeruginosa (Pao1) as a function of nitrate concentration under anaerobic and aerobic conditions. Very low levels of basal expression are shown under non-denitrifying conditions (i.e. absence of nitrate, in both aerobic and anaerobic conditions); anaerobiosis is not required for high levels of enzyme production in the presence of nitrate. A Pseudomonas aeruginosa strain, mutated in the nitrite reductase gene, has been obtained by gene replacement. This mutant, the first of this species described up to now, is unable to grow under anaerobic conditions in the presence of nitrate. The anaerobic growth can be restored by complementation with the wild-type gene.

Kinetics of Pseudomonas aeruginosa cytochrome c551 and cytochrome oxidase oxidation by Co(phen)3(3+) and Mn(CyDTA)(H2O)-.

The reaction between reduced Pseudomonas cytochrome c551 and cytochrome oxidase with two inorganic metal complexes, Co(phen)3(3+) and Mn(CyDTA)(H2O)-, has been followed by stopped-flow spectrophotometry. The electron transfer to cytochrome c551 by both reactants is a simple process, characterized by the following second-order rate constant: k = 4.8 X 10(4) M-1 sec-1 in the case of Co(phen)3(3+) and k = 2.3 X 10(4) M-1 sec-1 in the case of Mn(CyDTA)(H2O)-. The reaction of the c-heme of the oxidase with both metal complexes is somewhat heterogeneous, the overall process being characterized by the following second-order rate constants: k = 1.7 X 10(3) M-1 sec-1 with Co(phen)3(3+) and k = 4.3 X 10(4) M-1 sec-1 with Mn(CyDTA)(H2O)- as oxidants; under CO (which binds to the d1-heme) the former constant increases by a factor of 2, while the latter does not change significantly. The oxidation of the d1-heme of the oxidase by Co(phen)3(3+) occurs via intramolecular electron transfer to the c-heme, a direct bimolecular transfer from the complex being operative only at high metal complex concentrations; when Mn(CyDTA)(H2O)- is the oxidant, the bimolecular oxidation of the d1-heme competes successfully with the intramolecular electron transfer.

Electron transfer kinetics between Rhus vernicifera stellacyanin and cytochrome c (horse heart cytochrome c and Pseudomonas cytochrome c551).

The electron transfer reactions between Rhus vernicifera stellacyanin and either horse heart cytochrome c or Pseudomonas aeruginosa cytochrome c551 were investigated by rapid reaction techniques. The time course of electron transfer is monophasic under all conditions, and thus consistent with a simple formulation of the reaction. Both stopped-flow and temperature-jump experiments yield equilibrium constants in reasonable agreement with values calculated from the redox potentials. The differences in reaction rate between the two cytochromes and stellacyanin are discussed in terms of the Marcus theory.

Monomeric Pseudomonas aeruginosa nitrite reductase: preparation, characterization, and kinetic properties.

Monomeric nitrite reductase in an active form has been prepared by controlled succinylation of the dimeric native enzyme of Pseudomonas aeruginosa and subsequent purification. The monomeric enzyme has an optical spectrum indistinguishable from that of the native enzyme. On the other hand, circular dichroic spectra in the heme and peptide absorption regions show differences with respect to the dimer that indicate that the chemical modification and/or the dissociation into monomers somewhat perturb the chromophores' environment and the secondary structure. The (negatively charged) monomer is unable to oxidize its physiological substrates, azurin and cytochrome c551. This loss of activity is not due to monomerization, but is linked to the total net charge of the succinylated molecule, which interestingly enough acquires the ability to oxidize efficiently eukaryotic cytochrome c (which is not a substrate of the native dimeric enzyme). Stopped-flow studies show that the reduced monomer reacts with oxygen with a kinetic pattern similar to that shown by the dimeric enzyme. However, a higher reaction rate in the bimolecular binding of oxygen and a much higher oxygen affinity than for the native enzyme are observed. The evidence reported in this paper indicates that the dimeric state of Pseudomonas nitrite reductase is not a prerequisite for the ferrocytochrome c-oxygen oxidoreductase activity of this enzyme.

Isolation and characterization of the d1 domain of Pseudomonas aeruginosa nitrite reductase.

Proteolitic digestion of nitrite reductase from Pseudomonas aeruginosa allows to obtain and purify a domain containing only the d1 heme and constituted by two noncovalently bound peptides. This d1 domain catayzes oxygen consumption, and binds carbon monoxide with a kinetic constant slightly higher than the parental dimeric holoenzyme. The capacity to oxidize the physiological substrate, cytochrome c551, is lost, even when the proteolytic c heme domain is added to this reaction mixture. This finding suggests that the two domains do not have a significant affinity for each other, and are kept together only by being part of the same polypeptide.

Properties of cytochrome c modified by attachment to a carbohydrate polymer.

By enzymic digestion of the polysaccharide part of the covalent complex between cytochrome c and Sephadex G-200, a new water-soluble cytochrome c derivative is obtained (called cytochrome cr). Measurement of the free amino groups of this derivative indicates that on average the molar ratio between cytochrome c and polysaccharide is close to 1. Chemical determination of the sugar content gives a value of approx. 24000 for the molecular weight of cytochrome cr. On these bases the soluble cytochrome cr complex may be thought of as a folded protein to which a long polysaccharide tail is covalently bound. The functional behaviour of cytochrome cr is much more similar to that of the native molecule than to that of the insoluble complex (cytochrome ci). In particular the kinetics of the reaction of cytochrome cr and cytochrome cn (native) with ascorbate, ferrocyanide-ferricyanide, O2 and cytochrome c oxidase were investigated in considerable detail. The results of these experiments, together with the observation that the insoluble complex of cytochrome c is a very poor substrate of cytochrome c oxidase [Colosimo, Brunori & Antonini (1976) Biochem. J. 153, (657-661], indicate that hindrance effects constraining the approach between cytochrome cr and its oxidase are of greater importance than specific chemical modifications in determining the functional behavior of the protein.

A temperature-jump study of the electron transfer reactions in Hansenula anomala flavocytochrome b2.

Temperature-jump experiments on flavocytochrome b2 were carried out at different levels of heme reduction at pH 7.0 and 6.0, and as a function of pyruvate concentration. The relaxation, corresponding to an increase in the concentration of reduced heme, is in no case a simple process. AtpH 7.0 the mean reciprocal relaxation time is 1/tau* = 190 s-1, independent of enzyme concentration, wavelength of observation and percentage of heme reduction. Flavin semiquinone has been identified as the major electron donor to the heme in this process. At the same pH the presence of pyruvate in the millimolar concentration range increases the relaxation rate and affects its amplitude. The latter effect could be accounted for by a change in redox equilibria between heme and flavin upon pyruvate binding. At pH 6.0 the relaxation pattern depends more clearly on the level of heme reduction. A rapid process (tau-1 = 2500 s-1), predominant at high percentages of reduced heme, has been assigned to the reduction of heme by flavin hydroquinone, while the slower process (tau-1 = 350 s-1), essentially the only one present at or below 50% of heme reduction, has been ascribed to the reduction of heme by flavin semiquinone. These results are discussed in relation to the catalytic mechanism of the enzyme.

Expression in Escherichia coli of the flavin and the haem domains of Hansenula anomala flavocytochrome b2 (flavodehydrogenase and b2 core) and characterization of the recombinant proteins.

The flavin and haem domains of Hansenula anomala flavocytochrome b2 have been independently expressed in Escherichia coli. The flavin domain activity, studied only in the total cellular extract, owing to its instability, has characteristics very similar to those of the flavin domain obtained by proteolysis. The haem domain (r-core) has been purified to homogeneity and characterized in detail from spectroscopic and functional points of view. Spectral differences with respect to the domain produced by proteolysis (p-core) were found using resonance Raman and c.d. spectroscopy and have been interpreted in terms of changes in haem-protein interactions. However, this structural difference is functionally silent, since the r-core is able to reduce cytochrome c with the same efficiency as the proteolytic domain.

Kinetics of electron transfer between two Hansenula anomala flavocytochrome b2 derivatives and two simple copper proteins (azurin and stellacyanin).

Two derivatives of Hansenula anomala flavocytochrome b2 have been prepared, one deprived of the flavin prosthetic group (deflavocytochrome b2), and the other consisting of the heme-b-carrying globule (b2 core). The redox potential of the heme in the two derivatives is -5 (+/- 5) mV and -10 (+/- 5) mV respectively, fairly similar to the value of -20 (+/- 5) mV reported for the holoenzyme, indicating a minor effect of the flavin and of the flavodehydrogenase domain on heme potential. The kinetics of azurin and stellacyanin reduction by both derivatives have been investigated. At pH 7.0, I = 0.2 M and 20 degrees C the second-order rate constants are: k = 8 X 10(5) M-1 S-1 for azurin reduction by deflavocytochrome b2; k = 1.6 X 10(6) M-1 S-1 for azurin reduction by b2 core; k = 1 X 10(7) M-1 S-1 for stellacyanin reduction by deflavocytochrome b2; k = 3 X 10(7) M-1 S-1 for stellacyanin reduction by b2 core. The change in pH markedly affects the kinetics in the case of azurin, but has no effect on stellacyanin reduction. The change in ionic strength has a significant effect when deflavocytochrome b2 is the reductant, indicating that the flavodehydrogenase domain plays a role in the stabilization of the transient kinetic complex by means of electrostatic interactions. The kinetic results are discussed in the framework of the Marcus theory.

Expression of Pseudomonas aeruginosa nitrite reductase in Pseudomonas putida and characterization of the recombinant protein.

Nitrite reductase from Pseudomonas aeruginosa has been successfully expressed in Pseudomonas putida. The purified recombinant enzyme contains haem c but no haem d1. Nonetheless, like the holoenzyme from Ps. aeruginosa, it is a stable dimer (molecular mass 120 kDa), and electron transfer to oxidized azurin is biphasic and follows bimolecular kinetics (k1 = 1.5 x 10(5) and k2 = 2.2 x 10(4) M-1.s-1). Unlike the chemically produced apoenzyme, recombinant nitrite reductase containing only haem c is water-soluble, stable at neutral pH and can be quantitatively reconstituted with haem d1, yielding a holoenzyme with the same properties as that expressed by Ps. aeruginosa (namely optical and c.d. spectra, molecular mass, cytochrome c551 oxidase activity and CO-binding kinetics).

Electron transfer in zinc-reconstituted nitrite reductase from Pseudomonas aeruginosa.

1. The catalytic cycle of the haem-containing nitrite reductase (NIR) from Pseudomonas aeruginosa involves electron transfer between the two prosthetic groups of the enzyme, the c-haem and the d1-haem; this reaction was shown to be slow by stopped-flow analysis. The recombinant enzyme, expressed in Pseudomonas putida, contains the c-haem but no d1-haem; we have reconstituted this protein with Zn-protoporphyrin IX in the place of the d1-haem. 2. Photoexcitation of Zn-NIR is followed by electron transfer from the triplet excited state of the Zn-porphyrin to the oxidized c-haem, with a rate constant of 7 x 10(5) s-1; since the intermediate with reduced c-haem is not significantly populated, we conclude that the back reaction is probably as fast. 3. Even taking into account that in the native NIR the driving force is close to zero, the rate constant for the c-->d1 electron transfer, estimated from our experiments, is still much higher than that observed by stopped flow (k = 0.3 s-1) using reduced azurin as the electron donor. This finding may be a direct kinetic indication that reduction of the d1-haem is associated with a substantial reorganization of the co-ordination of the metal, as shown by spectroscopy of the oxidized and reduced NIR.

Transient kinetic studies of Neurospora crassa cytochrome c oxidase.

The reaction of Neurospora crassa cytochrome c oxidase with CO was studied by flash-photolysis and rapid-mixing experiments, leading to the determination of the association and dissociation rate constants (7 X 10(4) M-1 X s-1 and 0.02s-1 respectively). Pre-steady-state kinetic investigations of the catalytic properties of the enzyme showed that under proper conditions Neurospora cytochrome c oxidase can be 'pulsed', i.e. activated, like the mammalian enzyme. The 'pulsed' species is spectroscopically different from the 'resting' one, and the decay into the 'resting' state is fast (t1/2 approx. 3 min).