Two-step selective formation of three disulfide bridges in the synthesis of the C-terminal epidermal growth factor-like domain in human blood coagulation factor IX.

The 45-residue C-terminal EGF-like domain in human blood coagulation factor IX has been synthesized by a 2-step method to form selectively 3 disulfide bridges. Four out of 6 cysteines are blocked with either trityl or 4-methyl-benzyl, and the remaining 2 cysteines are blocked with acetamidomethyl (Acm). In the first step, 4 free cysteinyl thiols are released concurrently with the removal of all protecting groups except Acm and are oxidized to form 1 of the 3 possible isomers containing 2 pairs of disulfides. In the second step, iodine is used to remove the Acm groups to yield the third disulfide bridge. This approach reduces the number of possible disulfide bridging patterns from 15 to 3. To determine the optimal protecting group strategy, 3 peptides are synthesized, each with Acm blocking 1 of the 3 pairs of cysteines involved in disulfide bridges: Cys5 to Cys16 (Cys 1-3), Cys12 to Cys26 (Cys 2-4), or Cys28 to Cys41 (Cys 5-6). Only the peptide having the Cys 2-4 pair blocked with Acm forms the desired disulfide isomer (Cys 1-3/5-6) in high yield after the first step folding, as identified by proteolytic digestion in conjunction with mass spectrometric peptide mapping. Thus, the choice of which pair of cysteines to block with Acm is critically important. In the case of EGF-like peptides, it is better to place the Acm blocking groups on one of the pairs of cysteines involved in the crossing of disulfide bonds.

Sequence-specific 1H NMR assignments, secondary structure, and location of the calcium binding site in the first epidermal growth factor like domain of blood coagulation factor IX.

Factor IX is a blood clotting protein that contains three regions, including a gamma-carboxyglutamic acid (Gla) domain, two tandemly connected epidermal growth factor like (EGF-like) domains, and a serine protease region. The protein exhibits a high-affinity calcium binding site in the first EGF-like domain, in addition to calcium binding in the Gla domain. The first EGF-like domain, factor IX (45-87), has been synthesized. Sequence-specific resonance assignment of the peptide has been made by using 2D NMR techniques, and its secondary structure has been determined. The protein is found to have two antiparallel beta-sheets, and preliminary distance geometry calculations indicate that the protein has two domains, separated by Trp28, with the overall structure being similar to that of EGF. An NMR investigation of the calcium-bound first EGF-like domain indicates the presence and location of a calcium binding site involving residues on both strands of one of the beta-sheets as well as the N-terminal region of the peptide. These results suggest that calcium binding in the first EGF-like domain could induce long-range (possibly interdomain) conformational changes in factor IX, rather than causing structural alterations in the EGF-like domain itself.

13C-NMR of Clostridium pasteurianum ferredoxin after reductive methylation of the amines using [13C]formaldehyde.

Clostridium pasteurianum 2(4Fe-4S) ferredoxin has been reductively methylated using [13C]formaldehyde and sodium cyanoborohydride. Lys3 and the N-terminal alanine, the only amines in the protein, are both dimethylated by this procedure. 13C-NMR titration of the apo, oxidized and reduced modified ferrodoxin indicate that the lysine pK is slightly over 10 in all three forms of the protein. In contrast, the N-terminal alanine shifts from a pK of 7.7 in the apoprotein to greater than 9 in both the oxidized and reduced modified ferredoxin. The unexpectedly high pK observed for the N-terminus is consistent with the presence of an ion pair in both the oxidized and reduced native forms of the protein. The methylated ferrodoxin is considerably less stable than the native protein, indicating an important role for the amines in protein stability.

Spectroscopic studies of the seven-iron-containing ferredoxins from Azotobacter vinelandii and Thermus thermophilus.

The seven-iron-containing ferredoxins from Azotobacter vinelandii and Thermus thermophilus have been investigated by low-temperature magnetic circular dichroism (MCD) and electron paramagnetic resonance (EPR) spectroscopies and room temperature ultraviolet-visible absorption spectroscopy. The results confirm the presence of one trinuclear and one tetranuclear iron-sulfur cluster in both ferredoxins and facilitate comparison of the electronic and magnetic properties of the oxidized and reduced [3Fe-xS] clusters. MCD magnetization data are consistent with an S = 2 ground state for both reduced [3Fe-xS] clusters, but indicate differences in the rhombicity of the zero-field splittings. The data permit rationalization of the absence of a delta M = 4 EPR transition for the reduced [3Fe-xS] cluster in A. vinelandii ferredoxin I. Spectroscopic studies of anaerobically isolated A. vinelandii ferredoxin I do not support the hypothesis that the [3Fe-xS] cluster arises as a result of aerial oxidative damage to a [4Fe-4S] cluster during isolation. The possibility that two distinct forms of [3Fe-xS] clusters can exist in A. vinelandii ferredoxin I was investigated by spectroscopic studies as a function of pH. The results reveal two distinct and interconvertible forms of the reduced [3Fe-xS] cluster, but do not permit rationalization of the inconsistencies in the structural data that have been reported for the oxidized clusters.

The lack of a solvent accessible hydroxide or water ligand to iron at the 3Fe center of Azotobacter vinelandii ferredoxin I.

The X-ray crystal structure of Azotobacter vinelandii ferredoxin I (FdI) describes a planar 3Fe-3S center in which one of the iron atoms is ligated to a solvent accessible oxo ligand, presumably from water or hydroxide (Ghosh et al., (1982) J. Mol. Biol. 158, 73-109). Efforts to displace the proposed oxo ligand with cyanide were unsuccessful, even in 80% dimethylsulfoxide. In addition, comparison of the electron spin echo envelopes for H2O- and D2O-equilibrated samples of FdI showed only a slight deuterium modulation, far less than would be expected were water to be bound as an iron ligand. These results do not support the presence of a solvent accessible oxo ligand to the 3Fe center as described in the X-ray crystal structure.

Origin of the pH dependence of the midpoint reduction potential in Clostridium pasteurianum ferredoxin:oxidation state-dependent hydrogen ion association.

The origin of the dependence of E1/2 on pH exhibited by Clostridium pasteurianum 2(4Fe-4S) ferredoxin has been investigated. The results show that oxidation state-dependent pK values, which may arise from sites on the iron-sulfur centers, are responsible for the pH effect. Based on a model of two equivalent protonation sites/molecule, values of 7.4 for pKox and 8.9 for pKrd were obtained. The results of experiments which monitor changes in the hydrogen ion concentration with changes in protein oxidation state are reported. The magnitude of the changes in pH on reduction or reoxidation of the protein are in reasonable agreement with the proposed model. The conformation of C. pasteurianum ferredoxin was examined by nmr, epr, and CD spectroscopies to rule out a pH-dependent conformation equilibrium as the origin of the pH effect.

Proton magnetic resonance studies of Azotobacter vinelandii ferredoxin I. Evidence for a difference in coordination of the 3Fe centers in azotobacter vinelandii ferredoxin I and desulfovibrio gigas ferredoxin II.

Proton magnetic resonance studies have been made of Azotobacter vinelandii ferredoxin I. This protein contains a low potential 3Fe-3S center (Emp = -424 mV) and a high potential 4Fe-4S center (Emp = +320 mV). A series of five single proton resonances are visible downfield of 11 ppm in the isolated form of the protein. On reduction of the protein the three most downfield resonances are no longer visible and no new resonances are observed. These resonances are assigned to alpha-CH cysteinyl protons on residues 8, 20, and 49 which coordinate the 3Fe center. The two remaining downfield resonances are altered on oxidation of the protein, and are assigned to beta-CH2 cysteinyl protons on residues bound to the high potential 4Fe center. Comparison of the reported NMR spectrum of Desulfovibrio gigas ferredoxin II (Moura, J. J. G., Xavier, A. V., Bruschi, M., and Le Gall, J. (1977) Biochim. Biophys. Acta 459, 278-289) to that of A. vinelandii ferredoxin I is made. The 3Fe centers found in D. gigas ferredoxin Ii exhibit a reduction potential almost 300 mV more positive than the 3Fe center in A. vinelandii ferredoxin I. Evidence is presented that the 3Fe centers in the two proteins are not co-ordinated identically, and arguments are made which suggest that a small noncysteinyl ligand, modeled as a nonprotein oxygen atom in the x-ray structure A. vinelandii ferredoxin I, may be replaced in D. gigas ferredoxin II by a glutamyl epsilon-oxygen linkage to an iron atom. Further, it is noted that such a change could be responsible for the significant difference in reduction potential observed between the 3Fe centers in these two proteins.

Magnetic interactions between dysprosium complexes and two soluble iron-sulfur proteins.

A tetranuclear ferredoxin from Rhodopseudomonas gelatinosa [4Fe-4S](+2,+3) has been examined by electron paramagnetic resonance techniques. The temperature-dependence and relaxation characteristics of the spectral lines indicate that the spin-lattice interaction is described at low temperatures by a T2 law which gives way to a T9 Raman relaxation as the temperature is raised. At higher temperatures an Orbach process becomes dominant. In the presence of dysprosium complexes the relaxation and line widths are modified. From crystallographic structure determinations of similar proteins we are able to relate the dysprosium effects to the spatial separation between the complex and the tetranuclear cluster. This scale is then tested against a ferredoxin from Clostridium pasteurianum which contains two tetranuclear clusters, [4Fe-4S](+1,+2). We find that for these soluble iron-sulfur proteins the dysprosium complexes form a shell at the protein surface. The magnetic interaction between the clusters and the complexes altering the relaxation time goes as r-6, while the low temperature line broadening is described by an r-3 dipole interaction.

Determination of cooperative interaction between clusters in Clostridium pasteurianum 2 (4Fe-4S) ferredoxin.

The effect of reducing one 4Fe-4S cluster in Clostridium pasteurianum 2 (4Fe-4S) ferredoxin on the reduction potential of the unreduced cluster has been investigated. While such an effect is suggested by both the x-ray structure of Peptococcus aerogenes 2 (4F-4S) ferredoxin and the polypeptide conformational change on reduction present in clostridial-type 2 (4Fe-4S) ferredoxins, present studies indicate that cluster-cluster cooperative interaction is not strong enough to be of functional importance in these proteins.

Direct assignment of the cysteinyl, the slowly exchangeable, and the aromatic ring 1H nuclear magnetic resonances in clostridial-type ferredoxins.

We have directly assigned the 1H NMR corresponding to the cysteinyl protons, the slowly exchangeable protons, and the aromatic ring protons in the 1H NMR spectrum of Clostridium acidi-urici ferredoxin by isotopic labeling and 13C NMR decoupling techniques. We also show that the resonance pattern in the 8- to 20-ppm (from 2,2-dimethyl-2-sialapentanesulfonic acid) region of the 1H NMR spectra of oxidized Clostridium acidi-urici, Clostridium pasteurianum, Clostridium perfringens, and Peptococcus aerogenes ferredoxins are very similar, and we assign the resonances in this region by analogy with the spectrum of C. acidi-urici ferredoxin. The 1H NMR spectra of the beta protons of the cysteinyl residues of these ferredoxins differ, however, from the 1H NMR spectra of equivalent beta protons of the methylene carbon atoms bonded via a sulfur atom to [4Fe-4S] clusters in synthetic inorganic analogues. In the spectra of the synthetic compounds, the beta protons appear as a single resonance shifted 10 ppm from its unbonded reference position. In the spectra of oxidized clostridial ferredoxins, the cysteinyl beta protons appear as a series of at least eight resolved resonances with shifts that range from 6 to 14 ppm, relative to the free amino acid resonance position. This difference in the spectra of the protein and the synthetic compounds probably results from the fact that the equivalent beta protons of the synthetic compounds are not constrained and are free to rotate and thus assume the same average orientation with respect to the [4Fe-4S] cluster. The shift pattern in the 9- to 14-ppm region is identical in three different clostridial ferredoxins. This suggests that the molecular environments of the corresponding cysteinyl residues are identical. Significant differences in the resonance positions occur, however, in the 14- to 18-ppm region, suggesting that the physical environments of these cysteinyl residues differ. This may reflect differences in the orientation of the corresponding cysteinyl residues relative to the [4Fe-4S] clusters or differences in charge density at the cysteinyl beta protons or both. The slowly exchangeable protons were identified by comparing the 1H NMR spectra of ferredoxins reconstituted in H2O and 2H2O. The remaining resonances in the 8- to 20-ppm region were assigned to each of the 2 tyrosyl residues in C. acidi-urici ferredoxin. This was done by comparing the 1H NMR spectra of C. acidi-urici [(3',5'-2H2)Tyr]ferredoxin and C. acidi-urici [PHE2]ferredoxin with that of C. acidi-urici native ferredoxin.

Characterization of two soluble ferredoxins as distinct from bound iron-sulfur proteins in the photosynthetic bacterium Rhodospirillum rubrum.

In an earlier investigation (Shanmugam, K. T., Buchanan, B. B., and Arnon, D. I. (1972) Biochim. Biophys. Acta 256, 477-486) the extraction of ferredoxin from Rhodospirillum rubrum cells with the aid of a detergent (Triton X-100) and acetone revealed the existence of two types of ferredoxin (I and II) and led to the conclusion that both are membrane-bound. In the present investigation, ferredoxin and acid-labile sulfur analyses of photosynthetic membranes (chromatophores) and soluble protein extracts of the photosynthetic bacteria R. rubrum and Rhodopseudomonas spheroides showed that ferredoxins I and II are primarily components of the soluble protein fraction. After their removal, washed R. rubrum chromatophores were found to contain a considerable amount of tightly bound iron-sulfur protein(s), as evidenced by acid-labile sulfur and electron paramagnetic resonance analyses. Thus, like all other photosynthetic cells examined to date, R. rubrum cells contain both soluble ferredoxins and iron-sulfur proteins tightly bound to photosynthetic membranes. The molecular weights of ferredoxins I and II from photosynthetically grown R. rubrum cells were found to be 8,800 and 14,500, respectively. Using these molecular weights, the molar extinction coefficients at 390 nm for ferredoxins I and II were determined to be 30.3 and 17.2 mM-1 CM-1, respectively. Ferredoxin I contains 8 non-heme iron and 8 acid-labile sulfur atoms per molecule; ferredoxin II contains 4 non-heme iron and 4 acid-labile sulfur atoms per molecule. Ferredoxin I was found only in photosynthetically grown cells whereas ferredoxin II was present in both light- and dark-grown cells. Ferredoxin II from both light- and dark-grown cells has the same molecular weight (14,500) and absorption spectrum and has 4 iron and 4 acid-labile sulfur atoms per molecule. Low temperature electron paramagnetic resonance spectra of oxidized and photoreduced ferredoxins I and II from R. rubrum were recorded. The EPR spectrum of oxidized ferredoxin II exhibited a single resonance line at g = 2.012. Oxidized ferredoxin I, however, exhibited a spectrum that may arise from the superimposition of two resonance lines near g = 2.012. Photoreduced ferredoxin II displayed a rhombic EPR spectrum with a g value of 1.94. Photoreduced ferredoxin I exhibited a similar EPR spectrum at a temperature of 16 K, but when the temperature was lowered to 4.5 K the spectrum of ferredoxin I changed. This temperature-dependent spectrum may result from a weak spin-spin interaction between two iron-sulfur clusters. These results are consistent with the conclusion that R. rubrum ferredoxins I and II are, respectively, 8 iron/8 sulfur and 4 iron/4sulfur proteins.

High and low reduction potential 4Fe-4S clusters in Azotobacter vinelandii (4Fe-4S) 2ferredoxin I. Influence of the polypeptide on the reduction potentials.

Azotobacter vinelandii (4Fe-4S)2 ferredoxin I (Fd I) is an electron transfer protein with Mr equals 14,500 and Eo equals -420 mv. It exhibits and EPR signal of g equals 2.01 in its isolated form. This resonance is almost identical with the signal that originates from a "super-oxidized" state of the 4Fe-4S cluster of potassium ferricyanide-treated Clostridium ferredoxin. A cluster that exhibits this EPR signal at g equals 2.01 is in the same formal oxidation state as the cluster in oxidized Chromatium High-Potential-Iron-Protein (HiPIP). On photoreduction of Fd I with spinach chloroplast fragments, the resonance at g equals 2.01 vanishes and no EPR signal is observed. This EPR behavior is analogous to that of reduced HiPIP, which also fails to exhibit an EPR spectrum. These characteristics suggest that a cluster in A. vinelandii Fd I functions between the same pair of states on reduction as does the cluster in HiPIP, but with a midpoint reduction potential of -420 mv in contrast to the value of +350 mv characteristic of HiPIP. Quantitative EPR and stoichoimetry studies showed that only one 4Fe-4S cluster in this (4Fe-4S)2 ferredoxin is reduced. Oxidation of Fd I with potassium ferricyanide results in the uptake of 1 electron/mol as determined by quantitative EPR spectroscopy. This indicates that a cluster in Fd I shows no electron paramagnetic resonance in the isolated form of the protein accepts an electron on oxidation, as indicated by the EPR spectrum, and becomes paramagnetic. The EPR behavior of this oxidizable cluster indicates that it also functions between the same pair of oxidation states as does the Fe-S cluster in HiPIP. The midpoint reduction potential of this cluster is approximately +340 mv. A. vinelandii Fd I is the first example of an iron-sulfur protein which contains both a high potential cluster (approximately +340 mv) and a low potential cluster (-420 mv). Both Fe-S clusters appear to function between the same pair of oxidation states as the single Fe-S cluster in Chromatium HiPIP, although the midpoint reduction potentials of the two clusters are approximately 760 mv different.

Synthesis and properties of Clostridium acidi-urici (Leu2)-ferredoxin: a function of the peptide chain and evidence against the direct role of the aromatic residues in electron transfer.

Tyrosyl or other aromatic residues generally occur in two conserved positions in the peptide chain of clostridial-type ferredoxins and have been implicated in the electron transfer function of these iron-sulfur proteins. We have prepared and determined some of the properties of a derivative of Clostridium acidi-urici ferredoxin, [Leu(2)]-ferredoxin, in which a leucyl residue has been substituted for the tyrosyl residue in position 2 from the amino terminus. [Leu(2)]-ferredoxin is fully active as an electron carrier in two biological assays, the phosphoroclastic enzyme system and the ferredoxin-dependent reduction of cytochrome c in the presence of ferredoxin-TPN reductase and TPNH. Quantitative electron paramagnetic resonance experiments indicate that [Leu(2)]-ferredoxin accepts nearly two electrons upon enzymatic reduction by pyruvate-ferredoxin oxidoreductase and an excess of pyruvate. If electron transfer to an iron-sulfur cluster is the rate-limiting step in the assays used, and if the rate of electron transfer through Tyr(30) is not much faster than through Tyr(2), these results indicate that the primary pathway of electron transfer in clostridial-type ferredoxins is not via Tyr or other aromatic amino-acid residues. The syntheses of other ferredoxin derivatives with amino-acid substitutions or deletions in positions 1 and 2 indicate that a large bulky residue, but not necessarily an aromatic residue, is needed in position 2 for the stability of this ferredoxin. The residue in position 2, therefore, appears to act as a hydrophobic shield for an iron-sulfur cluster.