Preliminary X-ray studies of the tetra-heme cytochrome c3 and the octa-heme cytochrome c3 from Desulfovibrio gigas

A tetra-heme and an octa-heme cytochrome c3 from the sulfate bacterium Desulfovibrio gigas have been crystallized. Diffraction quality crystals of the tetra-heme cytochrome are obtained from solution by the addition of polyethylene glycol at pH 6.5. The crystals are orthorhombic, space group P2(1)2(1)2 with unit cell parameters a = 42.27 A, b = 52.54 A and c = 52.83 A. The octa-heme cytochrome crystals develop from low ionic strength solutions of phosphate or Tris-Cl in the pH range 6.2-7.6. The crystals belong to the trigonal system, space group P3(1) or the enantiomorph P3(2), with unit cell parameters a = b = 57.4 A, c = 97.3 A, gamma = 120 degrees. Single crystal diffraction studies of the structures of these two low-potential cytochromes are in progress.     

Cytochrome c: ion binding and redox properties. Studies on ferri and ferro forms of horse, bovine, and tuna cytochrome c

The ion binding properties of horse, bovine, and tuna cytochrome c (both oxidized and reduced) have been measured using a combination of ultrafiltration, neutron activation, and ion chromatography. The ions investigated were chloride, phosphate, and Tris-cacodylate. Ion chromatography and neutron activation analysis techniques were employed to determine the concentration of free anions. Binding constants are obtained from modified Scatchard plots (in the range of 10-2000 M-1). The redox potentials for cytochrome c at different ionic strengths, pH 7.0, have been determined. In this paper we report the ionic strength and ion binding effects on the redox properties of horse, bovine, and tuna cytochrome c. Potential versus ionic strength dependence for horse, bovine, and tuna cytochrome c from the experimental data were compared with a theoretical model.     

Preliminary crystallographic studies on human apo-lactoferrin in its native and deglycosylated forms

Human apo-lactoferrin in both native and deglycosylated forms has been purified, and crystals obtained by dialysis against low ionic strength buffer solutions. The crystals of native apo-lactoferrin are orthorhombic, space group P2(1)2(1)2(1) with cell dimensions a = 222.0 A, b = 115.6 A, c = 77.8 A and have two protein molecules per asymmetric unit. Two crystal forms of deglycosylated apo-lactoferrin have been obtained. One is orthorhombic, space group P2(1)2(1)2(1), with cell dimensions a = 152.1 A, b = 94.6 A, c = 55.8 A. The second is tetragonal, space group I4, with cell dimensions a = b = 189.4 A, c = 55.1 A. Both of the latter have only one molecule per asymmetric unit, and are suitable for high-resolution X-ray structure analysis.     

Crystallization and crystallographic characterization of the iron-sulfur-containing DNA-repair enzyme endonuclease III from Escherichia coli.

Endonuclease III from Escherichia coli is an iron-sulfur enzyme possessing both DNA N-glycosylase and apurinic/apyrimidinic lyase activities. It could serve to repair damaged thymine residues in DNA via base excision-repair. We have crystallized endonuclease III by a combination of dialysis and seeding techniques after exploration of a wide variety of precipitants which failed to yield macroscopic crystals. Important features of the optimized crystallization include: the use of 5 to 10% glycerol, a temperature of 15 degrees C, controlled dialysis to decrease ionic strength and macroseeding using a 200 mM-NaCl transfer buffer to dissolve microcrystalline contamination. The crystals belong to space group P2(1)2(1)2(1) with unit cell dimensions of a = 48.5 A, b = 65.8 A, c = 86.8 A, alpha = beta = gamma = 90 degrees, have one 23 kDa monomer per asymmetric unit, and diffract to 1.84 A. A native anomalous Patterson map located the iron-sulfur cluster and reaffirmed its existence. The reported crystallization procedures ensure an ample supply of crystals for the extensive heavy-atom derivative search necessary for this labile iron-sulfur enzyme. The elucidation of endonuclease III structure will facilitate not only the understanding of glycosylase and lyase mechanisms but also the structure and function of this new class of iron-sulfur proteins.     

Crystallization of the DpnM methylase from the DpnII restriction system of Streptococcus pneumoniae

Three proteins, two DNA methylases and an endonuclease, from the DpnII restriction system of Streptococcus pneumoniae recognize the DNA sequence 5' GATC 3' but have very different amino acid sequences, which make them interesting subjects for structural determination. A purification procedure was developed that conveniently yields milligram amounts of the DpnM methylase. The DpnM protein tends to precipitate at reduced ionic strength, and this property was exploited to yield well-formed bipyramidal crystals. By X-ray diffraction, the crystals of DpnM were found to be orthorhombic, with cell dimensions a = 56.9 A, b = 68.2 A, c = 84.5 A; systematic absences identify the space group as P2(1)2(1)2(1). Diffraction extends beyond 3 A, so the crystals may allow structural determination at atomic resolution.     

The binding of porphyrin cytochrome c to yeast cytochrome c peroxidase. A fluorescence study of the number of sites and their sensitivity to salt

Porphyrin c, the iron-free derivative of cytochrome c, is a reasonably good model for cytochrome c binding to cytochrome c peroxidase (CcP). It binds with the same stoichiometry but only one-quarter as tightly as cytochrome c. CcP (resting, FeIII) and CcP X CN can both bind up to two molecules of porphyrin c. The binding of the first porphyrin c is tight (kd = 1 X 10(-9) M, pH 6, ionic strength mu = 0, 4 degrees C) and results in quenching of the porphyrin c fluorescence. The binding is sensitive to ionic strength. The binding of the second porphyrin c is looser (Kd unknown) and does not result in quenching of the porphyrin fluorescence. The binding of porphyrin c to the cyano form and the resting forms of CcP cannot be distinguished by our methods. ES is the first acceptor of electrons from c(II) and can bind at least two molecules of porphyrin c. The binding of the first porphyrin c is extremely tight, results in substantial quenching and is insensitive to ionic strength. The binding of porphyrin c to the loose site (Kd = 2 X 10(-9) M, pH 6, 4 degrees C, mu = 0) results, unlike the resting and cyano forms, in quenching of fluorescence of the second porphyrin c. The binding of the second porphyrin c to ES is sensitive to ionic strength. The calculated distances between porphyrin c and the hemes of CcP(FeIII) and ES are approximately 2.5 nm.     

The gpQ portal protein of bacteriophage P2 forms dodecameric connectors in crystals

Double-stranded bacteriophages code for a protein called a connector or portal protein that serves as the entry and exit portal for DNA during genome packaging and ejection, as well as the connection point between heads and tails, and possibly as a nucleator for capsid assembly. The gpQ connector protein from bacteriophage P2 has been overexpressed in Escherichia coli and purified by sucrose gradient centrifugation. Negative stain electron microscopy and image analysis revealed a 135 A diameter dodecameric ring structure with a central 25 A hole. The connector showed a strong propensity to aggregate at low ionic strength and would form microcrystalline structures in solution. Consequently, the connectors were crystallized by hanging-drop vapor diffusion against low ionic strength buffer. Two crystal forms were observed: a P4(1)22 form with unit cell parameters a=b=96.33 A and c=454.42 A that diffracted X-rays to 4.5 A resolution and an I222 crystal form with a=168.86 A, b=171.88 A and c=168.68 A that diffracted to 4.1A resolution. Self-rotation functions confirmed the presence of 12-fold symmetry in the crystals.     

Single crystals of large ribosomal particles from Halobacterium marismortui diffract to 6 A

Large, well-ordered three-dimensional crystals of 50 S ribosomal subunits from Halobacterium marismortui have been obtained by seeding. The crystals have been characterized with synchrotron X-ray radiation as monoclinic, space group P2(1), with unit cell dimensions of a = 182(+/- 5) A, b = 584(+/- 10) A, c = 186(+/- 5) A, beta = 109 degrees. At 4 degrees C, the crystals (0.6 mm X 0.6 mm X 0.1 mm) diffract to 6 A resolution and are stable in the synchrotron beam for several hours. Compact packing is reflected from the crystallographic unit cell parameters and from electron micrographs of positively stained thin sections of embedded crystals.     

Characterization of single crystals of the large ribosomal particles from Bacillus stearothermophilus

Single, three-dimensional crystals of the 50 S ribosomal subunit from Bacillus stearothermophilus (strain NCA) have been characterized using a synchrotron X-ray source. The crystals are orthorhombic with unit cell dimensions: a = 350 A, b = 670 A, c = 905 A, and contain at least one 2-fold screw axis. With cooling to -2 degrees C, the large crystals (1.0 mm X 0.2 mm X 0.1 mm) diffract to 15 to 18 A resolution and are stable in the synchrotron beam for several hours. Despite the large cell dimensions, the reflections are readily resolved when the X-ray diffraction patterns are densitometered with a 25 microns faster.     

Some electron-transfer reactions involving carbodi-imide-modified cytochrome c.

The reaction kinetics of native and carbodi-imide-modified tuna and horse heart cytochromes c with both a strong (dithionite) and a relatively weak (ascorbate) reducing agent were studied over a wide range of conditions. In their reactions with dithionite both the native and modified cytochromes exhibit single exponential time courses. The effects of dithionite concentration and ionic strength on the rate of the reduction are complex and can best be explained in terms of the model proposed by Lambeth & Palmer [(1973) J. Biol. Chem. 248, 6095-6103]. According to this model, at low ionic strength the native proteins are reduced almost exclusively by S2O4(2-) whereas the modified proteins showed reactivity towards both S2O4(2-) and SO2.-. These findings are interpreted in terms of the different charge characteristics of the carbodi-imide-modified proteins relative to the native proteins. The findings that the modified proteins react with ascorbate in a biphasic manner are explained as arising from ascorbate binding to a reducible form of the protein, before electron transfer, with an equilibrium between the ascorbate-reducible form of the protein and a non-reducible form. Estimates were obtained for both the ascorbate equilibrium binding constant and the rate constant for the internal electron transfer for both the native and modified horse and tuna proteins. The effect of pH on the reactions indicates that the active reductant in all cases is ascorbate2-. The studies of ascorbate reactivity yield important information concerning the proposed correlation between ascorbate reducibility and the presence of a 695 nm-absorption band, and the study of dithionite reactivity illustrates the effect of protein charge and solution ionic strength on the relative contributions made by the species SO2.- and S2O4(2-) to the reduction of ferricytochrome c.     

Preliminary crystallographic studies on bovine lactoferrin

The purification of bovine lactoferrin, its crystallization at low ionic strength, and preliminary X-ray crystallographic data are reported. The crystals, which grow from a two-phase system, are radiation-stable and suitable for a medium-resolution X-ray analysis. They are orthorhombic, space group P2(1)2(1)2(1), with cell dimensions a = 138.4 A, b = 87.1 A, c = 73.6 A, and one protein molecule in the asymmetric unit.     

Separation of enzymically active bovine cytochrome c oxidase monomers and dimers by high performance liquid chromatography

The aggregation state of two types of bovine heart cytochrome c oxidase preparations in the presence of laurylmaltoside was investigated by high performance liquid chromatography in two buffers of ionic strengths of 388 mM and 45 mM, respectively. At high ionic strength, it was found that the Fowler cytochrome c oxidase preparation was monomeric (Mr = 2 X 10(5)), while monomers and dimers (2 X aa3, Mr = 4 X 10(5)) could be isolated from the Yonetani preparation. Under these conditions there was no rapid equilibrium between the two forms. Covalent cytochrome c oxidase-cytochrome c complexes were largely dimeric, and addition of ascorbate and cytochrome c to the oxidase also promoted dimerization. At low ionic strength (I = 45 mM) in the presence of laurylmaltoside the oxidase and the covalent complex with cytochrome c were largely monomeric. In the steady-state oxidation of ferrous horse heart cytochrome c, the monomeric enzyme displayed biphasic kinetics at I = 45 mM. This suggests that the presence of high- and low-affinity reactions is an intrinsic property of the cytochrome c oxidase monomer.     

Tuna cytochrome c at 2.0 A resolution. I.Ferricytochrome structure analysis.

The crystal structure of oxidized cytochrome c from tuna hearts has been solved by x-ray diffraction to a resolution of 2.0 A, using four isomorphous heavy atom derivatives. The crystals, space group P43, have 2 independent cytochrome molecules in the asymmetric repeating unit. No significant difference is seen between these 2 molecules, aside from conformations of a few surface side chains. The molecular folding observed is essentially that reported for tuna ferrocytochrome c. In particular, the ring of phenylalanine 83 lies against the heme group and closes the heme crevice, and is not swung out into the surroundings as had been believed from the 2.8 A horse ferricytochrome c structure.     

Crystallization and preliminary X-ray diffraction studies of a toxic crystal protein from a subspecies of Bacillus thuringiensis

The toxic crystal protein (Mr 64,000) from a subspecies of the bacterium Bacillus thuringiensis has been solubilized and recrystallized yielding diffraction quality crystals. Crystals are obtained by a change in pH and ionic strength using Na2CO3. They can also be obtained by a change in ionic strength only using NaBr as the precipitant. The space group of both forms is C222(1) with a = 133, b = 116, c = 104 A and one molecule/asymmetric unit. Still photographs show reflections to 3.0-A resolution.     

Kinetics and mechanism of the reduction of horse heart ferricytochrome c by glutathione.

A detailed investigation of the reduction of cytochrome c by glutathione has shown that the reaction proceeds through several steps. A rapid combination of the reducing agent with the cytochrome leads to the formation of a glutathione-cytochrome intermediate in which the glutathione most likely interacts with the edge of the heme moiety. The electron transfer takes place in a subsequent slower step. Since cytochrome c(III) exists in two conformational forms at neutral pH [Kujundzic, N., & Everse, J. (1978) Biochem. Biophys. Res. Commun. 82, 1211], the reduction of cytochrome c by glutathione may be represented by cyt c(III) + GS- reversible K1 cyt c(III) ... GS- reversible k1 products cyt c*(III) + GS- reversible K2 cyt c*(III) ... GS- reversible k2 products At 25 degrees C, pH 7.5, and an ionic strength of 1.0 (NaCl), k1 = 1.2 X 10(-3) S-1, k2 = 2.0 X 10(-3) S-1, k1 = 2.9 X 10(3) M-1, and K2 = 5.3 X 10(3) M-1. The reaction is catalyzed by trisulfides, and second-order rate constants of 4.55 X 10(3) and 7.14 X 10(3) M-1 S-1 were obtained for methyl trisulfide and cysteine trisulfide, respectively.     

Binding of spermidine to transfer ribonucleic acid

The binding of spermidine to yeast tRNAPhe and Escherichia coli tRNAGlu2 at low and high ionic strength was studied by equilibrium dialysis. Once corrected for the expected Donnan effect, the binding at low ionic strength obeys the simple relationship of equivalent binding sites, and cooperative binding of spermidine to tRNA could not be detected. At low ionic strength (0.013 M Na+ ion), tRNAPhe (yeast) has 13.9 +/- 2.3 strong spermidine binding sites per molecule with Kd = 1.39 X 10(-6) M and a few weak spermidine binding sites which were inaccessible to experimentation; tRNAGlu2 (E. coli) has 14.8 +/- 1.6 strong spermidine binding sites and 4.0 +/- 0.1 weak spermidine binding sites with Kd = 1.4 X 10(-6) M and Kd = 1.23 X 10(-4) M, respectively. At high ionic strength (0.12 M monovalent cation) and 0.01 M Mg2+, tRNAPhe (yeast) has approximately 13 strong spermidine binding sites with an apparent Kd = 3.4 X 10(-3) M while the dimeric complex tRNAPhe X tRNAGlu2 has 10.4 +/- 1.2 strong spermidine binding sites per monomer with an apparent Kd = 2.0 X 10(-3) M. In the presence of increasing Na+ ion or K+ ion concentration, spermidine binding data do not fit a model for competitive binding to tRNA by monovalent cations. Rather, analysis of binding data by the Debye-Hückel approximation results in a good fit of experimental data, indicating that monovalent cations form a counterion atmosphere about tRNA, thus decreasing electrostatic interactions. On the basis of equilibrium binding analyses, it is proposed that the binding of spermidine to tRNA occurs predominantly by electrostatic forces.     

Studies on nitrotyrosine-82 and aminotyrosine-82 derivatives of adrenodoxin. Effects of chemical modification on the complex formation with adrenodoxin reductase.

The coordination structure of the iron-sulfur center of the nitrotyrosine and the aminotyrosine derivates of bovine adrenodoxin was investigated by electron paramagnetic resonance spectroscopy. The reduced form of both modified samples exhibited signals identical with those for the native protein at g= 1.94 and g=2.01. From these results together with optical absorption and chemical analyses, it was concluded that the coordination structure of the iron-sulfur chromophore for both the derivatives was identical with the binuclear tetrahedral structure of native adrenodoxin. The configuration of the iron-binding area in nitro- and amino-adrenodoxin was studied by ovserving the circular dichroism spectra between 350 and 600 nm. The maxima for the nitro or amino derivatives were all identical with those for the native protein but different in the magnitude of their molar ellipticity. The molar ellipticities at 440 nm were 45.8 X 10(3), 14.5 X 10(3), and 9.5 X 10(6) deg cm2 per mol of iron for native adrenodoxin, nitro or amino derivative, respectively. These results suggest that the chemical modification of the tyrosine residue causes a conformational change in the iron-binding area. We have previously reported that the enzymatic activities of these reconstituted nitro and amino derivatives toware cytochrome c reduction in the presence of adrenodoxin reductase and reduced nicotinamide adenine dinucleotide phosphate were 19 and 7% of native adrenodoxin, respectively. The cytochrome c reductase activities of nitro- and aminoadrenodixin were drastically affected by the ionic strength of the assay medium, as found in native adrenodoxin. Fluorometric titration of the reductase with aminoadrenodoxin revealed that aminoadrenodoxin forms a 1:1 molar complex with the reductase. These results suggest that both the nitro and amino derivatives form a complex with the reductase. The dissociation constants of nitro- and aminoadrenodoxin for the reductase were 6.1 X 10(-7)M and 3.3 X 10(-7) M at mu = 0.04 and 1.9 X 10(-6) M and 2.0 X 10(-6) M at mu = 0.20, respectively. Comparison of these values with those of native adrenodoxin (approximately 10(-9) M at mu = 0.04 and 2.2 X 10(-7) M at mu = 0.20) suggests that an increase in the dissociation constant for the reductase is responsible for the decreased electron transferring activity of the modified adrenodoxins.     

Electron-transfer reactions between flavodoxin semiquinone and c-type cytochromes: comparisons between various flavodoxins

As an extension of previous work from this laboratory using Clostridium pasteurianum flavodoxin [Tollin, G., Cheddar, G., Watkins, J. A., Meyer, T. E., & Cusanovich, M. A. (1984) Biochemistry 23, 6345-6349], we have measured the rate constants as a function of ionic strength for electron transfer from the semiquinones of Clostridium MP, Anacystis nidulans, and Azotobacter vinelandii flavodoxins to the following oxidants: cytochrome c from tuna and horse, Paracoccus denitrificans cytochrome c2, Pseudomonas aeruginosa cytochrome c-551, and ferricyanide. The rate constants extrapolated to infinite ionic strength (k infinity) for the C. MP flavodoxin are all slightly smaller than for the C. pasteurianum flavodoxin, as would be predicted on the basis of the higher redox potential of the C. MP protein. This indicates that there is a close similarity between the surface topographies of the two proteins in the vicinity of the coenzyme binding site. Moreover, the electrostatic interactions between the two flavodoxins and the various oxidants are also approximately the same. These studies justify our previous use of the crystallographic structure of the C. MP flavodoxin to interpret kinetic results obtained with the structurally uncharacterized C. pasteurianum flavodoxin. Despite their lower redox potentials, both Anacystis and Azotobacter flavodoxins are appreciably less reactive toward all of these oxidants (as much as 2 orders of magnitude in some cases) than are the Clostridium flavodoxins.(ABSTRACT TRUNCATED AT 250 WORDS)     

Crystallization, preliminary X-ray study and crystal activity of the hydrogenase from Desulfovibrio gigas

Hydrogenase (EC 1.12) from Desulfovibrio gigas is a dimeric enzyme (26 and 62 (X 10(3) Mr) that catalyzes the reversible oxidation of molecular hydrogen. Single crystals of hydrogenase have been produced using the hanging drop method, with either PEG (polyethylene glycol) 6000 or ammonium sulfate as precipitants at pH 6.5. X-ray examination of the crystals indicates that those obtained with ammonium sulfate are suitable for structure determination to at least 3.0 A resolution when synchrotron radiation Sources are used (1 A = 0.1 nm). The crystals are monoclinic, with space group C2, and cell dimensions a = 257.0 A, b = 184.7 A, c = 148.3 A and beta = 101.3 degrees, and contain between four and ten molecules per asymmetric unit. The enzyme can be reactivated within the crystals under reducing conditions without crystal damage.     

Self-aggregation of surfactant protein A

Environmental factors of physiological relevance such as pH, calcium, ionic strength, and temperature can affect the state of self-aggregation of surfactant protein A (SP-A). We have studied the secondary structure of different SP-A aggregates and analyzed their fluorescence characteristics. (a) We found that self-aggregation of SP-A can be Ca(2+)-dependent. The concentration of Ca(2+) needed for half-maximal self-association (K(a)(Ca)()2+) depended on the presence of salts. Thus, at low ionic strength, K(a)(Ca)()2+ was 2.3 mM, whereas at physiological ionic strength, K(a)(Ca)()2+ was 2.35 microM. Circular dichroism and fluorescence measurements of Ca(2+)-dependent SP-A aggregates indicated that those protein aggregates formed in the absence of NaCl are structurally different from those formed in its presence. (b) We found that self-aggregation of SP-A can be pH-dependent. Self-aggregation of SP-A induced by H(+) was highly influenced by the presence of salts, which reduced the extent of self-association of the protein. The presence of both salts and Ca(2+) attenuated even more the effects of acidic media on SP-A self-aggregation. (c) We found that self-aggregation of SP-A can be temperature-dependent. At 20 degrees C, SP-A underwent self-aggregation at physiological but not at low ionic strength, in the presence of EDTA. All of these aggregates were dissociated by either adding EDTA (a), increasing the pH to neutral pH (b), or increasing the temperature to 37 degrees C (c). Dissociation of Ca(2+)-induced protein aggregates at low ionic strength was accompanied by an irreversible loss of both SP-A secondary structure and SP-A-dependent lipid aggregation properties. On the other hand, temperature-dependent experiments indicated that a structurally intact collagen-like domain was required for either Ca(2+)- or Ca(2+)/Na(+)-induced SP-A self-aggregation but not for H(+)-induced protein aggregation.