Temperature and driving force dependence of the folding rate of reduced horse heart cytochrome c.

Utilizing the stability difference between the ferro and ferri forms of horse heart cytochrome c (cyt c), folding of reduced cyt c was triggered by laser-induced reduction of unfolded oxidized cyt c. Measurements were made of the kinetics of the main folding phase (1 ms-10 s) in which collapsed reduced cyt c transforms to the native conformation. The folding rates were studied extensively as a function of temperature (5-75 degrees C) and guanidine hydrochloride (GdnHCl) concentration (1.6-4.9 M). At constant [GdnHCl], the Arrhenius plot of the folding rate constant (k) is nonlinear. At temperatures above 40 degrees C, the decrease in protein stability counteracts the expected increase in folding rate. Introducing free energy (DeltaG), derived from protein stability data, into the Eyring and Arrhenius equations leads to: ln k = ln(k(b)T/h) + DeltaS()/R - DeltaH()/RT - theta(m)DeltaG/RT = ln A - E(a)/RT - theta(m)DeltaG/RT, where theta(m) is the ratio between the denaturant dependence of the folding rate and the stability. By using this equation at constant DeltaG [or constant equilibrium constant (K)], linear Arrhenius plots are obtained. For the main folding phase of reduced cyt c, a positive DeltaS() is obtained indicating that the transition state is less ordered than the reactant. A model is proposed in which reduced cyt c first collapses into a compact intermediate, which needs to expand to reach the transition state of the rate-limiting folding reaction.

Cytochrome c folding triggered by electron transfer.

BACKGROUND: Experimental and theoretical studies of protein folding suggest that the free-energy change associated with the folding process is a primary factor in determining folding rates. We have recently developed a photochemical electron-transfer-triggering method to study protein-folding kinetics over a wide range of folding free energies. Here, we have used this technique to investigate the relationship between folding rate and free-energy change using cytochromes c from horse (h-cyt c) and yeast (y-cyt c), which have similar backbone folds but different amino-acid sequences and, consequently, distinct folding energies. RESULTS: The folding free energies for oxidized and reduced h-cyt c and y-cyt c are linear functions of the denaturant (guanidine hydrochloride) concentration, but the concentration required to unfold half of the protein is 1.5 M lower for y-cyt c. We measured the folding rates of reduced h-cyt c and y-cyt c over a range of guanidine hydrochloride concentrations at two temperatures. When driving forces are matched at the appropriate denaturant concentrations, the two homologs have comparable folding rates. The activation free energies for folding h-cyt c and y-cyt c are linearly dependent on the folding free energies. The slopes of these lines are similar (approximately 0.4) for the two proteins, suggesting an early transition state along the folding reaction coordinate. CONCLUSIONS: The free-energy relationships found for h-cyt c and y-cyt c folding kinetics imply that the height of the barrier to folding depends upon the relative stabilities of the unfolded and folded states. The striking correspondence in rate/free-energy profiles for h-cyt c and y-cyt c suggests that, despite low sequence homology, they follow similar folding pathways.

Protein folding triggered by electron transfer.

Rapid photochemical electron injection into unfolded ferricytochrome c titrated with 2.3 to 4.6 M guanidine hydrochloride (GuHCL) at pH 7 and 40 degrees C produced unfolded ferrocytochrome, which then converted to the folded protein. Two folding phases were observed: a fast process with a time constant of 40 microseconds (4.6 M GuHCL), and a slower phase with a rate constant of 90 +/- 20 per second (2.3 M GuHCL). The activation free energy for the slow step varied linearly with GuHCL concentration; the rate constant, extrapolated to aqueous solution, was 7600 per second. Electron-transfer methods can bridge the nanosecond to millisecond measurement time gap for protein folding.

Structure of the azurin mutant Phe114Ala from Pseudomonas aeruginosa at 2.6 A resolution.

The crystal structure of azurin mutant Phe114Ala from Pseudomonas aeruginosa has been solved by molecular replacement. The final crystallographic R value is 0.185 for 9832 reflections to a resolution of 2.6 A. The root-mean-square deviation for main-chain atom positions is 0.020 A between the four independent monomers in the asymmetric unit. The mutant Ala114 crystallized from PEG 4000 in a new crystal form and the crystals are monoclinic, P2(1), a= 51.0, b = 83.6, c= 66.4 A and beta = 110.5 degrees. The four molecules in the asymmetric unit are packed as a dimer of dimers and are related by an approximate twofold axis. The dimer packing and the dimer contact region are very similar to that of the Alcaligenes denitrificans azurin dimer. The mutation was performed at residue Phe114, which exhibits a pi-electron overlap with the copper ligand His117, to investigate its suggested role in the electron self-exchange reaction. Removal of steric constrains from the phenylalanine side chain created a somewhat different geometry around the copper site with an increased mobility of His117 resulting in an enlarged Cu-N length which may be responsible for the slight differences obtained in the spectral properties of the mutant versus the wild-type protein.

Structure of Pseudomonas aeruginosai zinc azurin mutant Asn47Asp at 2.4 A resolution.

The Pseudomonas aeruginosa azurin mutant Asn47Asp has been isolated, its spectroscopic and kinetic properties characterized, and the X-ray crystal structure of its zinc derivative determined. While the optical and electron paramagnetic resonance spectra as well as the electron-transfer activity of the mutant are very similar to the wild-type values, the Asn47Asp reduction potential is slightly increased by 20 mV. The mutant crystallized in the orthorhombic space group P2(1)2(1)2(1) with cell dimensions a = 57.8, b = 81.5 and c = 112.6 A. There are four molecules in the asymmetric unit, packed as a tetramer which consists of two independent dimers. The zinc site of this mutant structure is similar to the wild-type zinc azurin and, in particular, the metal-binding site is almost identical to the site found in the wild-type zinc-azurin structure [Nar, Huber, Messerschmidt, Filippou, Barth, Jaquinod, Kamp & Canters (1992). Eur. J. Biochem. 205, 1123-1129]. The Asp47 side chain at that mutation site takes on a very similar orientation to Asn47 in the wild-type structure preserving the two hydrogen bonds with the neighbouring Thr113 NH and O(gamma)H. Therefore, the increased reduction potential of the mutant is probably a result of an altered charge distribution close to the metal site.

Intramolecular electron transfer in single-site-mutated azurins.

Single-site mutants of the blue, single-copper protein, azurin, from Pseudomonas aeruginosa were reduced by CO2- radicals in pulse radiolysis experiments. The single disulfide group was reduced directly by CO2- with rates similar to those of the native protein [Farver, O., & Pecht, I. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 6968-6972]. The RSSR- radical produced in the above reaction was reoxidized in a slower intramolecular electron-transfer process (30-70 s-1 at 298 K) concomitant with a further reduction of the Cu(II) ion. The temperature dependence of the latter rates was determined and used to derive information on the possible effects of the mutations. The substitution of residue Phe114, situated on the opposite side of Cu relative to the disulfide, by Ala resulted in a rate increase by a factor of almost 2. By assuming that this effect is only due to an increase in driving force, lambda = 135 kJ mol-1 for the reorganization energy was derived. When Trp48, situated midway between the donor and the acceptor, was replaced by Leu or Met, only a small change in the rate of intramolecular electron transfer was observed, indicating that the aromatic residue in this position is apparently only marginally involved in electron transfer in wild-type azurin. Pathway calculations also suggest that a longer, through-backbone path is more efficient than the shorter one involving Trp48. The former pathway yields an exponential decay factor, beta, of 6.6 nm-1. Another mutation, raising the electron-transfer driving force, was produced by changing the Cu ligand Met121 to Leu, which increases the reduction potential by 100 mV.(ABSTRACT TRUNCATED AT 250 WORDS)

Reduction potentials and their pH dependence in site-directed-mutant forms of azurin from Pseudomonas aeruginosa.

A spectroelectrochemical method has been used to determine the reduction potential of the copper site in wild-type and 22 mutant forms of azurin from Pseudomonas aeruginosa at 25 degrees C and in the range pH 4-8; the effect of buffers and ionic strength on the potentials has also been studied. Amino-acid residues changed include Met121, which provides an S atom at a distance of about 0.3 nm from the metal, some amino acids in the hydrophobic patch, other residues believed to be important in electron transfer with physiological partners and some internal amino acids. The observed potentials span a range of about 300 mV. In all cases the potentials increase with decreasing pH, but the pKa values describing the pH dependence are essentially unchanged except in three mutants, where they change by pH 0.6-1.1 (up in one and down in two). The largest potential changes were found in some Met121 mutants, at which position large hydrophobic residues raise the potential, whereas negatively charged residues lower it; a decreased potential is also found in the Met121-->End mutant, which probably has H2O coordinated to the metal. Gly45 has its carbonyl group coordinated to copper, but the potential of Gly45-->Ala is close to that of the wild type. Some substitutions in the hydrophobic patch cause an increase in the potential, whereas substitutions involving His35 and Glu91 do not result in significant changes. No single mechanism for tuning the potential of the copper site can be discerned, but in many cases there are probably indirect effects of the protein conformation causing changes in metal-ligand interactions.

Structural characterization of azurin from Pseudomonas aeruginosa and some of its methionine-121 mutants.

Azurin from Pseudomonas aeruginosa and two mutants where the methionine ligand has been mutated have been studied in order to directly investigate the functional and structural significance of this ligand in the blue copper proteins. Reduction potentials, X-ray absorption fine structure (XAFS), electron paramagnetic resonance (EPR), and optical spectra are obtained in an attempt to provide a direct correlation between the spectrochemical properties and the immediate structure of this redox center.

Restoration of a lost metal-binding site: construction of two different copper sites into a subunit of the E. coli cytochrome o quinol oxidase complex.

The cupredoxin fold, a Greek key beta-barrel, is a common structural motif in a family of small blue copper proteins and a subdomain in many multicopper oxidases. Here we show that a cupredoxin domain is present in subunit II of cytochrome c and quinol oxidase complexes. In the former complex this subunit is thought to bind a copper centre called CuA which is missing from the latter complex. We have expressed the C-terminal fragment of the membrane-bound CyoA subunit of the Escherichia coli cytochrome o quinol oxidase as a water-soluble protein. Two mutants have been designed into the CyoA fragment. The optical spectrum shows that one mutant is similar to blue copper proteins. The second mutant has an optical spectrum and redox potential like the purple copper site in nitrous oxide reductase (N2OR). This site is closely related to CuA, which is the copper centre typical of cytochrome c oxidase. The electron paramagnetic resonance (EPR) spectra of both this mutant and the entire cytochrome o complex, into which the CuA site has been introduced, are similar to the EPR spectra of the native CuA site in cytochrome oxidase. These results give the first experimental evidence that CuA is bound to the subunit II of cytochrome c oxidase and open a new way to study this peculiar copper site.

Crystallization and preliminary crystallographic data for the azurin mutant Ala 114 from Pseudomonas aeruginosa.

The site-specific mutant alanine 114 of the blue copper protein azurin from Pseudomonas aeruginosa in Escherichia coli has been crystallized from PEG 4000 in a new crystal form compared to the wild type utilizing the hanging-drop procedure. The crystals are blue well-formed prisms. Monoclinic, P2(1), a = 51.03 (5), b = 83.36 (5), c = 66.30 (6) A and beta = 111.0 (1) degrees. 14,875 reflections up to 2.7 A have been collected using a modified Syntex P2(1) automated four-circle diffractometer.

Cassette mutagenesis of Met121 in azurin from Pseudomonas aeruginosa.

Cassette mutagenesis was used to exchange the suggested copper ligand Met121 in azurin to all other amino acids, and a stop codon. The mutant proteins were characterized by optical absorption spectroscopy and EPR. At low pH, all mutants exhibit the characteristics of a blue type 1 copper protein, indicating that methionine is not needed to create a blue copper site. At high pH, the Glu121 and the Lys121 mutants constitute a new form of protein-bound copper that is outside the range of type 1 copper.

Modification of the electron-transfer sites of Pseudomonas aeruginosa azurin by site-directed mutagenesis.

Site-directed mutagenesis of the structural gene for azurin from Pseudomonas aeruginosa has been used to prepare azurins in which amino acid residues in two separate electron-transfer sites have been changed: His-35-Lys and Glu-91-Gln at one site and Phe-114-Ala at the other. The charge-transfer band and the EPR spectrum are the same as in the wild-type protein in the first two mutants, whereas in the Phe-114-Ala azurin, the optical band is shifted downwards by 7 nm and the copper hyperfine splitting is decreased by 4.10(-4)/cm. This protein also shows an increase of 20-40 mV in the reduction potential compared to the other azurins. The potentials of all four azurins decrease with increasing pH in phosphate but not in zwitterionic buffers with high ionic strength. The rate constant for electron exchange with cytochrome c551 is unchanged compared to the wild-type protein in the Phe-114-Ala azurin, but is increased in the other two mutant proteins. The results suggest that Glu-91 is not important for the interaction with cytochrome c551 and that His-35 plays no critical role in the electron transfer to the copper site.

Expression of the blue copper protein azurin from Pseudomonas aeruginosa in Escherichia coli.

The structural gene for the blue copper protein azurin from Pseudomonas aeruginosa has been subcloned in different expression plasmid vectors. The highest yield of expression was obtained when the gene with its native ribosome-binding site was placed downstream of the lac promoter in plasmid pUC18. The protein is exported to the periplasmic space in Escherichia coli and the amount corresponds to 27% of the total protein content in the periplasmic space. The preprotein is cleaved correctly according to N-terminal sequencing of the purified protein. Azurin has been purified in large amounts and is spectroscopically indistinguishable from the protein purified from P. aeruginosa.