Functional characterization of Fdx1: evidence for an evolutionary relationship between P450-type and ISC-type ferredoxins

Ferredoxins are ubiquitous proteins with electron transfer activity involved in a variety of biological processes. In this work, we investigated the characteristics and function of Fdx1 from Sorangium cellulosum So ce56 by using a combination of bioinformatics and of biochemical/biophysical approaches. We were able to experimentally confirm a role of Fdx1 in the iron-sulfur cluster biosynthesis by in vitro reduction studies with cluster-loaded So ce56 IscU and by transfer studies of the cluster from the latter protein to apo-aconitase A. Moreover, we found that Fdx1 can replace mammalian adrenodoxin in supporting the activity of bovine CYP11A1. This makes S. cellulosum Fdx1 the first prokaryotic ferredoxin reported to functionally interact with this mammalian enzyme. Although the interaction with CYP11A1 is non-physiological, this is—to the best of our knowledge—the first study to experimentally prove the activity of a postulated ISC-type ferredoxin in both the ISC assembly and a cytochrome P450 system. This proves that a single ferredoxin can be structurally able to provide electrons to both cytochromes P450 and IscU and thus support different biochemical processes. Combining this finding with phylogenetic and evolutionary trace analyses led us to propose the evolution of eukaryotic mitochondrial P450-type ferredoxins and ISC-type ferredoxins from a common prokaryotic ISC-type ancestor.     

Formation of a linear [3Fe-4S] cluster in a seven-iron ferredoxin triggered by polypeptide unfolding

Cubic iron-sulfur ([Fe-S]) clusters are common inorganic cofactors in proteins. The presence of a linear [3Fe-4S] cluster in a protein was first observed in beef-heart aconitase at high pH, where the protein structure was perturbed. Not long ago, the same linear cluster was discovered upon unfolding of a thermophilic di-cluster seven-iron ferredoxin, suggesting a more general relevance for this type of linear clusters in Nature. Since structure-induced cluster rearrangements may be important regulatory, on-going processes in living systems, we decided to further characterize the formation of the linear iron-sulfur cluster observed upon ferredoxin unfolding. Here we present a kinetic investigation of parameters that affect the linear-cluster formation and disassembly in the Sulfolobus acidocaldarius seven-iron ferredoxin. We find the linear cluster to be an intermediate on the protein-mediated cluster-degradation pathway under a wide range of pH and denaturant conditions. The linear species forms in parallel with secondary-structure disappearance. In contrast, the disassembly rate constant for the linear cluster is independent of denaturant concentration but depends strongly on solution pH. At high pH, the disassembly rate is slower and the linear iron-sulfur species has a longer lifetime, than at low pH.     

Iron-sulfur cluster assembly: characterization of IscA and evidence for a specific and functional complex with ferredoxin

The synthesis of iron-sulfur clusters in Escherichia coli is believed to require a complex protein machinery encoded by the isc (iron-sulfur cluster) operon. The product of one member of this operon, IscA, has been overexpressed, purified, and characterized. It can assemble an air-sensitive [2Fe-2S] cluster as shown by UV-visible and resonance Raman spectroscopy. The metal form but not the apoform of IscA binds ferredoxin, another member of the isc operon, selectively, allowing transfer of iron and sulfide from IscA to ferredoxin and formation of the [2Fe-2S] holoferredoxin. These results thus suggest that IscA is involved in ferredoxin cluster assembly and activation. This is an important function because a functional ferredoxin is required for maturation of other cellular Fe-S proteins.     

Repair of nitric oxide-modified ferredoxin [2Fe-2S] cluster by cysteine desulfurase (IscS)

Iron-sulfur proteins are among the sensitive targets of the nitric oxide cytotoxicity. When Escherichia coli cells are exposed to nitric oxide, iron-sulfur clusters are modified forming protein-bound dinitrosyl iron complexes. Such modified protein dinitrosyl iron complexes are stable in vitro but are efficiently repaired in aerobically growing E. coli cells even without any new protein synthesis. Here we show that cysteine desulfurase encoded by the gene iscS of E. coli can directly convert the ferredoxin dinitrosyl iron complex to the ferredoxin [2Fe-2S] cluster in the presence of L-cysteine in vitro. A reassembly of the [2Fe-2S] cluster in the ferredoxin dinitrosyl iron complex does not require any addition of iron or other protein components. Furthermore, a complete removal of the dinitrosyl iron complex from ferredoxin prevents reassembly of the [2Fe-2S] cluster in the protein. The results suggest that cysteine desulfurase (IscS) together with L-cysteine can efficiently repair the nitric oxide-modified ferredoxin [2Fe-2S] cluster and that the iron center in the dinitrosyl iron complex may be recycled for the reassembly of iron-sulfur clusters in proteins.     

Protein control of iron-sulfur cluster redox potentials.

The relationship between the three-dimensional structures of iron-sulfur proteins and the redox potentials of their iron-sulfur clusters is of fundamental importance. We report calculations of the redox potentials of the [Fe4S4(S-cys)4]-2/-3 couple in four crystallographically characterized proteins: Azotobacter vinelandii ferredoxin I, Peptococcus aerogenes ferredoxin, Bacillus thermoproteolyticus ferredoxin, and Chromatium vinosum high potential iron protein (HiPIP). Our calculations use the "protein dipoles Langevin dipoles" microscopic electrostatic model, which includes both protein and solvent water. The variations in calculated redox potentials are in excellent agreement with experimental data. In particular, our results confirm the important role of amide groups close to the cluster in separating the potential of C. vinosum HiPIP from those of the other three proteins. However, the potentials of these latter exhibit a substantial range despite extremely similar amide group environments of their clusters. Our results show that the potentials in these proteins are tuned in part by varying the access of solvent water to the neighborhood of the cluster. Our calculations provide the first successful quantitative modeling of the protein control of iron-sulfur cluster redox potentials.     

The Arabidopsis chloroplastic NifU-like protein CnfU, which can act as an iron-sulfur cluster scaffold protein, is required for biogenesis of ferredoxin and photosystem I

The biosynthesis of iron-sulfur clusters is a highly regulated process involving several proteins. Among them, so-called scaffold proteins play pivotal roles in both the assembly and delivery of iron-sulfur clusters. Here, we report the identification of two chloroplast-localized NifU-like proteins, AtCnfU-V and AtCnfU-IVb, from Arabidopsis (Arabidopsis thaliana) with high sequence similarity to a cyanobacterial NifU-like protein that was proposed to serve as a molecular scaffold. AtCnfU-V is constitutively expressed in several tissues of Arabidopsis, whereas the expression of AtCnfU-IVb is prominent in the aerial parts. Mutant Arabidopsis lacking AtCnfU-V exhibited a dwarf phenotype with faint pale-green leaves and had drastically impaired photosystem I accumulation. Chloroplasts in the mutants also showed a decrease in both the amount of ferredoxin, a major electron carrier of the stroma that contains a [2Fe-2S] cluster, and in the in vitro activity of iron-sulfur cluster insertion into apo-ferredoxin. When expressed in Escherichia coli cells, AtCnfU-V formed a homodimer carrying a [2Fe-2S]-like cluster, and this cluster could be transferred to apo-ferredoxin in vitro to form holo-ferredoxin. We propose that AtCnfU has an important function as a molecular scaffold for iron-sulfur cluster biosynthesis in chloroplasts and thereby is required for biogenesis of ferredoxin and photosystem I.     

Assembly mechanism of [Fe2S2] cluster in ferredoxin from Acidithiobacillus ferrooxidans

Ferredoxin is a typical iron-sulfur protein that is ubiquitous in biological redox systems. This study investigates the in vitro assembly of a [Fe2S2] cluster in the ferredoxin from Acidithiobacillus ferrooxidans in the presence of three scaffold proteins: IscA, IscS, and IscU. The spectra and MALDI-TOF MS results for the reconstituted ferredoxin confirm that the iron-sulfur cluster was correctly assembled in the protein. The inactivation of cysteine desulfurase by L-allylglycine completely blocked any [Fe2S2] cluster assembly in the ferredoxin in E. coli, confirming that cysteine desulfurase is an essential component for iron-sulfur cluster assembly. The present results also provide strong evidence that [Fe2S2] cluster assembly in ferredoxin follows the AUS pathway.     

The iron electron-nuclear double resonance (ENDOR) of 4-Fe clusters in iron-sulfur proteins from Chromatium and Clostridium pasteurianum.

Iron electron-nuclear double resonance (ENDOR) measurements were made of the 4-Fe clusters in oxidized Chromatium high-potential iron-sulfur protein, dithionite-reduced high-potential iron-sulfur protein in 80% dimethylsulphoxide, fully reduced Clostridium pasteurianum ferredoxin in aqueous solution and in 80% dimethylsulfoxide. The hyperfine couplings determined show that: i) the electron distribution in each case is nearly symmetric; ii) there are two types of iron in oxidized high potential iron-sulfur protein; iii) only one type of iron is observed in each fully reduced 4-Fe cluster; iv) the data also suggest a greater electron delocalization onto the ligands as compared to the 2-Fe ferredoxins.     

Both human ferredoxins 1 and 2 and ferredoxin reductase are important for iron-sulfur cluster biogenesis

Ferredoxins are iron-sulfur proteins that have been studied for decades because of their role in facilitating the monooxygenase reactions catalyzed by p450 enzymes. More recently, studies in bacteria and yeast have demonstrated important roles for ferredoxin and ferredoxin reductase in iron-sulfur cluster assembly. The human genome contains two homologous ferredoxins, ferredoxin 1 (FDX1) and ferredoxin 2 (FDX2--formerly known as ferredoxin 1L). More recently, the roles of these two human ferredoxins in iron-sulfur cluster assembly were assessed, and it was concluded that FDX1 was important solely for its interaction with p450 enzymes to synthesize mitochondrial steroid precursors, whereas FDX2 was used for synthesis of iron-sulfur clusters, but not steroidogenesis. To further assess the role of the FDX-FDXR system in mammalian iron-sulfur cluster biogenesis, we performed siRNA studies on FDX1 and FDX2, on several human cell lines, using oligonucleotides identical to those previously used, along with new oligonucleotides that specifically targeted each gene. We concluded that both FDX1 and FDX2 were important in iron-sulfur cluster biogenesis. Loss of FDX1 activity disrupted activity of iron-sulfur cluster enzymes and cellular iron homeostasis, causing mitochondrial iron overload and cytosolic iron depletion. Moreover, knockdown of the sole human ferredoxin reductase, FDXR, diminished iron-sulfur cluster assembly and caused mitochondrial iron overload in conjunction with cytosolic depletion. Our studies suggest that interference with any of the three related genes, FDX1, FDX2 or FDXR, disrupts iron-sulfur cluster assembly and maintenance of normal cytosolic and mitochondrial iron homeostasis.     

铁硫簇的生物合成

铁硫簇在细胞的生物学过程中起着重要的作用,可参与电子传递、代谢控制和基因调节等过程。研究显示铁硫簇具有多样性,它的合成依赖于ISC和SUF系统,固氮酶中还需要NIF系统的参与。ISC系统由iscSUA-hscBA-fdx基因串编码,合成的是一类“管家”蛋白,适于在正常条件下表达。SUF系统由基因串sufABCDSE编码,常在恶劣环境如氧化应激和铁饥饿条件下表达。NIF系统由nifSU基因编码,适于固氮酶(厌氧条件下起作用)铁硫簇的合成。     

Characterization of iron-sulfur cluster assembly protein isca from Acidithiobacillus ferrooxidans

IscA is a key member of the iron-sulfur cluster assembly machinery found in bacteria and eukaryotes, but the mechanism of its function in the biogenesis of iron-sulfur cluster remains elusive. In this paper, we demonstrate that Acidithiobacillus ferrooxidans IscA is a [4Fe-4S] cluster binding protein, and it can bind iron in the presence of DTT with an apparent iron association constant of 4·10²⁰ M^?1. The iron binding in IscA can be promoted by oxygen through oxidizing ferrous iron to ferric iron. Furthermore, we show that the iron bound form of IscA can be converted to iron-sulfur cluster bound form in the presence of IscS and L-cysteine in vitro. Substitution of the invariant cysteine residues Cys35, Cys99, or Cys101 in IscA abolishes the iron binding activity of the protein; the IscA mutants that fail to bind iron are unable to assemble the iron-sulfur clusters. Further studies indicate that the iron-loaded IscA could act as an iron donor for the assembly of iron-sulfur clusters in the scaffold protein IscU in vitro. Taken together, these findings suggest that A. ferrooxidans IscA is not only an iron-sulfur protein, but also an iron binding protein that can act as an iron donor for biogenesis of iron-sulfur clusters.     

Location of the iron-sulfur clusters FA and FB in photosystem I: an electron paramagnetic resonance study of spin relaxation enhancement of P700+.

Photosystem I (PS I) mediates electron-transfer from plastocyanin to ferredoxin via a photochemically active chlorophyll dimer (P700), a monomeric chlorophyll electron acceptor (A0), a phylloquinone (A1), and three [4Fe-4S] clusters (FX/A/B). The sequence of electron-transfer events between the iron-sulfur cluster, FX, and ferredoxin is presently unclear. Owing to the presence of a 2-fold symmetry in the PsaC protein to which the iron-sulfur clusters F(A) and F(B) are bound, the spatial arrangement of these cofactors with respect to the C2-axis of symmetry in PS I is uncertain as well. An unequivocal determination of the spatial arrangement of the iron-sulfur clusters FA and FB within the protein is necessary to unravel the complete electron-transport chain in PS I. In the present study, we generate EPR signals from charge-separated spin pairs (P700+-FredX/A/B) in PS I and characterize them by progressive microwave power saturation measurements to determine the arrangement of the iron-sulfur clusters FX/A/B relative to P700. The microwave power at half saturation (P1/2) of P700+ is greater when both FA and FB are reduced in untreated PS I than when only FA is reduced in mercury-treated PS I. The experimental P1/2 values are compared to values calculated by using P700-FA/B crystallographic distances and assuming that either FA or FB is closer to P700+. On the basis of this comparison of experimental and theoretical values of spin relaxation enhancement effects on P700+ in P700+ [4Fe-4S]- charge-separated pairs, we find that iron-sulfur cluster FA is in closer proximity to P700 than the FB cluster.     

Enzymic synthesis of the 4Fe-4S clusters of Clostridium pasteurianum ferredoxin

Ex novo enzymic synthesis of the two 4Fe-4S clusters of Clostridium pasteurianum ferredoxin has been achieved by incubation of the apoprotein with catalytic amounts of the sulfurtransferase rhodanese in the presence of thiosulfate, DL-dihydrolipoate and ferric ammonium citrate. This enzymic reconstitution procedure was compared to a chemical one, in which the enzyme was replaced by sodium sulfide. A further comparison was made with the results previously obtained in the enzymic synthesis of the 2Fe-2S cluster of spinach ferredoxin, allowing the following conclusions to be drawn. The nature of the cluster to be inserted into the reconstituted iron-sulfur protein is determined by the apoprotein itself. The refolding of the structure of the iron-sulfur proteins around the newly inserted cluster is the rate-limiting step in both chemical and enzymic reconstitution. Rhodanese appears to play a role in the recovery of the native architecture of the reconstituted iron-sulfur protein(s). The extension to the 4Fe-4S centers of the rhodanese-based biosynthetic system allows this enzymic route to be proposed as a general way to the in vivo synthesis of iron-sulfur structures.     

Gene cloning, purification, and characterization of two cyanobacterial NifS homologs driving iron-sulfur cluster formation

Iron-sulfur proteins are essential in the photosynthetic system and many other biological processes. We have isolated and characterized enzymes driving the formation of iron-sulfur clusters from Synechocystis sp. PCC6803. Two genes (slr0387 and sll0704), showing similarity to nifS of Azotobacter vinelandii, were cloned, and their gene products (SsCsdl and SsCsd2) were purified. They catalyzed the desulfuration of L-cysteine. Reconstitution of a [2Fe-2S] cluster of cyanobacterial ferredoxin proceeded much faster in the presence of L-cysteine and either of these enzymes than when using sodium sulfide. These results suggest that SsCsdl and SsCsd2 facilitate the iron-sulfur cluster assembly by producing inorganic sulfur from L-cysteine. Synechocystis sp. PCC6803 has no gene coding for a protein with similarity to the N-terminal domain of NifU of A. vinelandii, which is believed to cooperate with NifS to assemble iron-sulfur clusters. Thus, the cluster formation in the cyanobacterium probably proceeds through a mechanism that is different from that in A. vinelandii.     

Sequence, assembly and evolution of a primordial ferredoxin from Thermotoga maritima.

A gene coding for the ferredoxin of the primordial, strictly anaerobic and hyperthermophilic bacterium Thermotoga maritima was cloned, sequenced and expressed in Escherichia coli. The ferredoxin gene encodes a polypeptide of 60 amino acids that incorporates a single 4Fe-4S cluster. T. maritima ferredoxin expressed in E. coli is a heat-stable, monomeric protein, the spectroscopic properties of which show that its 4Fe-4S cluster is correctly assembled within the mesophilic host, and that it remains stable during purification under aerobic conditions. Removal of the iron-sulfur cluster results in an apo-ferredoxin that has no detectable secondary structure. This observation indicates that in vivo formation of the ferredoxin structure is coupled to the insertion of the iron-sulfur cluster into the polypeptide chain. Sequence comparison of T. maritima ferredoxin with other 4Fe-4S ferredoxins revealed high sequence identities (75% and 50% respectively) to the ferredoxins from the hyperthermophilic members of the Archaea, Thermococcus litoralis and Pyrococcus furiosus. The high sequence similarity supports a close relationship between these extreme thermophilic organisms from different phylogenetic domains and suggests that ferredoxins with a single 4Fe-4S cluster are the primordial representatives of the whole protein family. This observation suggests a new model for the evolution of ferredoxins.     

Purification and biophysical characterization of a new [2Fe-2S] ferredoxin from Azotobacter vinelandii, a putative [Fe-S] cluster assembly/repair protein.

During the purification of site-directed mutant variants of Azotobacter vinelandii ferredoxin I (FdI), a pink protein, which was not observed in native FdI preparations, appeared to associate specifically with variants that had mutations in ligands to FdI [Fe-S] clusters. That protein, which we designate FdIV, has now been purified. NH(2)-terminal sequence analysis revealed that the protein is the product of a previously described gene, herein designated fdxD, that is in the A. vinelandii iscSUA operon that encodes proteins involved in iron-sulfur cluster assembly or repair. An apoprotein molecular mass of 12,434.03 +/- 0.21 Da was determined by mass spectrometry consistent with the known gene sequence. The monomeric protein was shown to contain a single [2Fe-2S](2+/+) cluster by UV/visible, CD, and EPR spectroscopies with a reduction potential of -344 mV versus the standard hydrogen electrode. When overexpressed in Escherichia coli, recombinant FdIV holoprotein was successfully assembled. However, the polypeptide of the recombinant protein was modified in some way such that the apoprotein molecular mass increased by 52 Da. Antibodies raised against FdIV and EPR spectroscopy were used to examine the relative levels of FdIV and FdI in various A. vinelandii strains leading to the conclusion that FdIV levels appear to be specifically increased under conditions where another protein, NADPH:ferredoxin reductase is also up-regulated. In that case, the fpr gene is known to be activated in response to oxidative stress. This suggests that the fdxD gene and other genes in the iron-sulfur cluster assembly or repair operon might be similarly up-regulated in response to oxidative stress.     

Isolation and Characterization of the Small Subunit of the Uptake Hydrogenase from the Cyanobacterium Nostoc punctiforme

In nitrogen-fixing cyanobacteria, hydrogen evolution is associated with hydrogenases and nitrogenase, making these enzymes interesting targets for genetic engineering aimed at increased hydrogen production. Nostoc punctiforme ATCC 29133 is a filamentous cyanobacterium that expresses the uptake hydrogenase HupSL in heterocysts under nitrogen-fixing conditions. Little is known about the structural and biophysical properties of HupSL. The small subunit, HupS, has been postulated to contain three iron-sulfur clusters, but the details regarding their nature have been unclear due to unusual cluster binding motifs in the amino acid sequence. We now report the cloning and heterologous expression of Nostoc punctiforme HupS as a fusion protein, f-HupS. We have characterized the anaerobically purified protein by UV-visible and EPR spectroscopies. Our results show that f-HupS contains three iron-sulfur clusters. UV-visible absorption of f-HupS has bands ∼340 and 420 nm, typical for iron-sulfur clusters. The EPR spectrum of the oxidized f-HupS shows a narrow g = 2.023 resonance, characteristic of a low-spin (S = ½) [3Fe-4S] cluster. The reduced f-HupS presents complex EPR spectra with overlapping resonances centered on g = 1.94, g = 1.91, and g = 1.88, typical of low-spin (S = ½) [4Fe-4S] clusters. Analysis of the spectroscopic data allowed us to distinguish between two species attributable to two distinct [4Fe-4S] clusters, in addition to the [3Fe-4S] cluster. This indicates that f-HupS binds [4Fe-4S] clusters despite the presence of unusual coordinating amino acids. Furthermore, our expression and purification of what seems to be an intact HupS protein allows future studies on the significance of ligand nature on redox properties of the iron-sulfur clusters of HupS.     

Studies on the degradation pathway of iron-sulfur centers during unfolding of a hyperstable ferredoxin: cluster dissociation,iron release and protein stability

The ferredoxin from the thermoacidophile Acidianus ambivalens is a representative of the archaeal family of di-cluster [3Fe-4S][4Fe-4S] ferredoxins. Previous studies have shown that these ferredoxins are intrinsically very stable and led to the suggestion that upon protein unfolding the iron-sulfur clusters degraded via linear three-iron sulfur center species, with 610 and 520 nm absorption bands, resembling those observed in purple aconitase. In this work, a kinetic and spectroscopic investigation on the alkaline chemical denaturation of the protein was performed in an attempt to elucidate the degradation pathway of the iron-sulfur centers in respect to protein unfolding events. For this purpose we investigated cluster dissociation, iron release and protein unfolding by complementary biophysical techniques. We found that shortly after initial protein unfolding, iron release proceeds monophasically at a rate comparable to that of cluster degradation, and that no typical EPR features of linear three-iron sulfur centers are observed. Further, it was observed that EDTA prevents formation of the transient bands and that sulfide significantly enhances its intensity and lifetime, even after protein unfolding. Altogether, our data suggest that iron sulfides, which are formed from the release of iron and sulfide resulting from cluster degradation during protein unfolding in alkaline conditions, are in fact responsible for the observed intermediate spectral species, thus disproving the hypothesis suggesting the presence of a linear three-iron center intermediate. Kinetic studies monitored by visible, fluorescence and UV second-derivative spectroscopies have elicited that upon initial perturbation of the tertiary structure the iron-sulfur centers start decomposing and that the presence of EDTA accelerates the process. Also, the presence of EDTA lowers the observed melting temperature in thermal ramp experiments and the midpoint denaturant concentration in equilibrium chemical unfolding experiments, further suggesting that the clusters also play a structural role in the maintenance of the conformation of the folded state.     

Gene Cloning,Purification, and Characterization of Two Cyanobacterial NifS Homologs Driving Iron-Sulfur Cluster Formation

Iron-sulfur proteins are essential in the photosynthetic system and many other biological processes. We have isolated and characterized enzymes driving the formation of iron-sulfur clusters from Synechocystis sp. PCC6803. Two genes (slr0387 and sll0704), showing similarity to nifS of Azotobacter vinelandii, were cloned, and their gene products (SsCsd1 and SsCsd2) were purified. They catalyzed the desulfuration of L-cysteine. Reconstitution of a [2Fe-2S] cluster of cyanobacterial ferredoxin proceeded much faster in the presence of L-cysteine and either of these enzymes than when using sodium sulfide. These results suggest that SsCsd1 and SsCsd2 facilitate the iron-sulfur cluster assembly by producing inorganic sulfur from L-cysteine. Synechocystis sp. PCC6803 has no gene coding for a protein with similarity to the N-terminal domain of NifU of A. vinelandii, which is believed to cooperate with NifS to assemble iron-sulfur clusters. Thus, the cluster formation in the cyanobacterium probably proceeds through a mechanism that is different from that in A. vinelandii.     

Laser flash photolysis studies of the kinetics of reduction of spinach and Clostridium ferredoxins by a viologen analogue: electrostatically controlled nonproductive complex formation and differential reactivity among the iron-sulfur clusters

We have studied the transient kinetics of electron transfer from a positively charged viologen analogue (propylene diquat), reduced by pulsed laser excitation of the deazariboflavin/EDTA system, to the net negatively charged ferredoxins from spinach and Clostridium pasteurianum. Spinach ferredoxin showed monophasic kinetics over the ionic strength range studied, consistent with the presence of only a single iron-sulfur center. Clostridium ferredoxin at low ionic strength showed biphasic kinetics, which indicates a differential reactivity of the two iron-sulfur centers of this molecule toward the electron donor. The kobsd values for the initial fast phase observed with Clostridium ferredoxin were ionic strength dependent, whereas the slow-phase kinetics were ionic strength independent. This correlates with the highly asymmetric charge distribution on the surface of the bacterial protein relative to the two iron-sulfur clusters. The kinetics corresponding to spinach ferredoxin reduction were also ionic strength dependent, and the results obtained with these kinetics and with the fast phase of the bacterial ferredoxin reduction were consistent with a mechanism involving electrostatically stabilized complex formation. For spinach ferredoxin, the second-order rate constant extrapolated to infinite ionic strength was 2-fold smaller, and the extrapolated limiting first-order rate constant was 10-fold smaller, than for Clostridium ferredoxin, indicating a smaller intrinsic reactivity of the spinach protein toward the electron donor. Differences in the rate constant values and the ionic strength dependencies with both ferredoxins are consistent with differences in cluster structure and environment and protein size and charge distribution. For both proteins, the total amount of ferredoxin reduced increased with the ionic strength.(ABSTRACT TRUNCATED AT 250 WORDS)