Heterologous expression of soluble fragments of cytochrome c552 acting as electron donor to the Paracoccus denitrificans cytochrome c oxidase

A membrane-bound c-type cytochrome, c552, acts as the electron mediator between the cytochrome bc1 complex and cytochrome c oxidase in the branched respiratory chain of the bacterium Paracoccus denitrificans. Unlike in mitochondria where a soluble cytochrome c interacts with both complexes, the bacterial c552, the product of the cycM gene, shows a tripartite structure, with an N-terminal membrane anchor separated from a typical class I cytochrome domain by a highly charged region. Two derivative fragments, lacking either only the membrane spanning region or both N-terminal domains, were constructed on the genetic level, and expressed in Escherichia coli cotransformed with the ccm gene cluster encoding host-specific cytochrome c maturation factors. High levels of cytochromes c were expressed and located in the periplasm as holo-proteins; both these purified c552 fragments are functional in electron transport to oxidase, as ascertained by kinetic measurements, and will prove useful for future structural studies of complex formation by NMR and X-ray diffraction.     

Complex formation and electron transfer between mitochondrial cytochrome c and flavocytochrome c552 from Chromatium vinosum

Flavocytochrome c552 from Chromatium vinosum catalyzes the oxidation of sulfide to sulfur using a soluble c-type cytochrome as an electron acceptor. Mitochondrial cytochrome c forms a stable complex with flavocytochrome c552 and may function as an alternative electron acceptor in vitro. The recognition site for flavocytochrome c552 on equine cytochrome c has been deduced by differential chemical modification of cytochrome c in the presence and absence of flavocytochrome c552 and by kinetic analysis of the sulfide:cytochrome c oxidoreductase activity of m-trifluoromethylphenylcarbamoyl-lysine derivatives of cytochrome c. As with mitochondrial redox partners, interaction occurs around the exposed heme edge at the "front face" of cytochrome c. However, the domain recognized by flavocytochrome c552 seems to extend to the right of the heme edge, whereas the site of interaction with mitochondrial cytochrome c oxidase and reductase is more to the left. Km but not Vmax of the electron transfer reaction with mitochondrial cytochrome c increases with increasing ionic strength. The correlation of chemical modification and ionic strength dependence data indicates that the electrostatic interaction between the two hemoproteins involves fewer ionic bonds than that with other redox partners of cytochrome c.     

Interaction of cytochrome c with cytochrome oxidase: two different docking scenarios

Cytochrome c is the specific and efficient electron transfer mediator between the two last redox complexes of the mitochondrial respiratory chain. Its interaction with both partner proteins, namely cytochrome c(1) (of complex III) and the hydrophilic Cu(A) domain (of subunit II of oxidase), is transient, and known to be guided mainly by electrostatic interactions, with a set of acidic residues on the presumed docking site on the Cu(A) domain surface and a complementary region of opposite charges exposed on cytochrome c. Information from recent structure determinations of oxidases from both mitochondria and bacteria, site-directed mutagenesis approaches, kinetic data obtained from the analysis of isolated soluble modules of interacting redox partners, and computational approaches have yielded new insights into the docking and electron transfer mechanisms. Here, we summarize and discuss recent results obtained from bacterial cytochrome c oxidases from both Paracoccus denitrificans, in which the primary electrostatic encounter most closely matches the mitochondrial situation, and the Thermus thermophilus ba(3) oxidase in which docking and electron transfer is predominantly based on hydrophobic interactions.     

Protein--protein docking of electron transfer complexes: cytochrome c oxidase and cytochrome c

Electron transferring protein complexes form only transiently and the crystal structures of electron transfer protein--protein complexes involving cytochrome c could so far be determined only for the pairs of yeast cytochrome c peroxidase (CcP) with iso-1-cytochrome c (iso-1-cyt c) and with horse heart cytochrome c (cyt c). This article presents models from computational docking for complexes of cytochrome c oxidase (COX) from Paracoccus denitrificans with horse heart cytochrome c, and with its physiological counterpart cytochrome c552 (c552). Initial docking is performed with the FTDOCK program, which permits an exhaustive search of translational and rotational space. A filtering procedure is then applied to reduce the number of complexes to a manageable number. In a final step of structural and energetic refinement, the complexes are optimized by rigid-body energy minimization with the molecular mechanics package CHARMM. This methodology was first tested on the CcP:iso-1-cyt c complex, in which the complex with the lowest CHARMM energy has an RMSD from the crystal structure of only 1.8 A (C(alpha) carbon atoms). Notably, the crystal conformation has an even lower energy. The same procedure was then applied to COX:cyt c and COX:c552. The lowest-energy COX:cyt c complex is very similar to a docking model previously described for the complex of bovine cytochrome c oxidase with horse heart cytochrome c. For the COX:c552 complex, cytochrome c552 is found in two different orientations, depending on whether it is docked against COX from a two-subunit or from a four-subunit crystal structure, respectively. Both conformations are discussed critically in the light of the available experimental data.     

Studies on cytochrome c oxidase activity of the cytochrome c1aa3 complex from Thermus thermophilus

Cytochrome oxidase from T. thermophilus is isolated as a noncovalent complex of cytochromes c1 and aa3 in which the four redox components of aa3 appear to be associated with a single approximately 55,000-D subunit while the heme C is associated with a approximately 33,000-D peptide (Yoshida, T., Lorence, R. M., Choc, M. G., Tarr, G. E., Findling, K. L., and Fee, J. A. (1983) J. Biol. Chem. 258, 112-123). We have examined the steady state transfer of electrons from ascorbate to oxygen by cytochrome c1aa3 as mediated by horse heart, Candida krusei, and T. thermophilus (c552) cytochromes c as well as tetramethylphenylenediamine (TMPD). These mediators exhibit simple Michaelis-Menten kinetic behavior yielding Vmax and KM values characteristic of the experimental conditions. Three classes of kinetic behavior were observed and are qualitatively discussed in terms of a reaction scheme. The data show that tetramethylphenyldiamine and cytochromes c react with the enzyme at independent sites; it is suggested that cytochrome c1 may efficiently transfer electrons to cytochrome aa3. When incorporated into phospholipid vesicles, the highly purified cytochrome c1aa3 was found to translocate one proton into the exterior medium for each molecule of cytochrome c552 oxidized. The combined results suggest that this bacterial enzyme functions in a manner generally identical with the more complex eucaryotic enzyme.     

Electron transfer complex between nitrous oxide reductase and cytochrome c552 from Pseudomonas nautica: kinetic, nuclear magnetic resonance, and docking studies

The multicopper enzyme nitrous oxide reductase (N 2OR) catalyzes the final step of denitrification, the two-electron reduction of N 2O to N 2. This enzyme is a functional homodimer containing two different multicopper sites: CuA and CuZ. CuA is a binuclear copper site that transfers electrons to the tetranuclear copper sulfide CuZ, the catalytic site. In this study, Pseudomonas nautica cytochrome c 552 was identified as the physiological electron donor. The kinetic data show differences when physiological and artificial electron donors are compared [cytochrome vs methylviologen (MV)]. In the presence of cytochrome c 552, the reaction rate is dependent on the ET reaction and independent of the N 2O concentration. With MV, electron donation is faster than substrate reduction. From the study of cytochrome c 552 concentration dependence, we estimate the following kinetic parameters: K m c 552 = 50.2 +/- 9.0 muM and V max c 552 = 1.8 +/- 0.6 units/mg. The N 2O concentration dependence indicates a K mN 2 O of 14.0 +/- 2.9 muM using MV as the electron donor. The pH effect on the kinetic parameters is different when MV or cytochrome c 552 is used as the electron donor (p K a = 6.6 or 8.3, respectively). The kinetic study also revealed the hydrophobic nature of the interaction, and direct electron transfer studies showed that CuA is the center that receives electrons from the physiological electron donor. The formation of the electron transfer complex was observed by (1)H NMR protein-protein titrations and was modeled with a molecular docking program (BiGGER). The proposed docked complexes corroborated the ET studies giving a large number of solutions in which cytochrome c 552 is placed near a hydrophobic patch located around the CuA center.     

Comparing substrate specificity between cytochrome c maturation and cytochrome c heme lyase systems for cytochrome c biogenesis

Hemes c are characterized by their covalent attachment to a polypeptide via a widely conserved CXXCH motif. There are multiple biological systems that facilitate heme c biogenesis. System I, the cytochrome c maturation (CCM) system, is found in many bacteria and is commonly employed in the maturation of bacterial cytochromes c in Escherichia coli-based expression systems. System III, cytochrome c heme lyase (CCHL), is an enzyme found in the mitochondria of many eukaryotes and is used for heterologous expression of mitochondrial holocytochromes c. To test CCM specificity, a series of Hydrogenobacter thermophilus cytochrome c(552) variants was successfully expressed and matured by the CCM system with CX(n)CH motifs where n = 1-4, further extending the known substrate flexibility of the CCM system by successful maturation of a bacterial cytochrome c with a novel CXCH motif. Horse cytochrome c variants with both expanded and contracted attachment motifs (n = 1-3) were also tested for expression and maturation by both CCM and CCHL, allowing direct comparison of CCM and CCHL substrate specificities. Successful maturation of horse cytochrome c by CCHL with an extended CXXXCH motif was observed, demonstrating that CCHL shares the ability of CCM to mature hemes c with extended heme attachment motifs. In contrast, two single amino acid mutants were found in horse cytochrome c that severely limit maturation by CCHL, yet were efficiently matured with CCM. These results identify potentially important residues for the substrate recognition of CCHL.     

Role of tryptophan 121 in the soluble CuA domain of cytochrome c oxidase: structure and electron transfer studies

To investigate the contribution of tryptophan-121 (Trp121) residue to the structure and function of soluble CuA domain of cytochrome c oxidase, three mutant proteins, Trp121Tyr, Trp121Leu and Trp121-deleted mutant of the soluble domain of Paracoccus versutus cytochrome c oxidase, were constructed and expressed in Escherichia coli BL21 (DE3). Optical spectral studies showed that both the coordination structure of the CuA center and the secondary structure of the protein were changed significantly in the Leu substitution and deletion mutants of Trp121. Their electron transfer activity with cytochrome c was inhibited severely, as shown in stopped-flow kinetic studies. However, the CuA center can be reconstructed in the Trp121Tyr mutant although its stability decreases compared with the wild-type protein. This mutant keeps the same secondary structure as the wild-type protein, but can only transfer electrons with cytochrome c at a rate of one-seventh-fold. Based on the information on the structure, we also investigated and analyzed the possible factors that affect electron transfer. It appears that the aromatic ring, the size of the side chain and the hydrogen bonding ability of the Trp121 are crucial to the structure and function of the soluble CuA domain.     

Kinetics of interprotein electron transfer between cytochrome c6 and the soluble CuA domain of cyanobacterial cytochrome c oxidase

Cytochrome c6 is a soluble metalloprotein located in the periplasmic space and the thylakoid lumen of many cyanobacteria and is known to carry electrons from cytochrome b6f to photosystem I. The CuA domain of cytochrome c oxidase, the terminal enzyme which catalyzes the four-electron reduction of molecular oxygen in the respiratory chains of mitochondria and many bacteria, also has a periplasmic location. In order to test whether cytochrome c6 could also function as a donor for cytochrome c oxidase, we investigated the kinetics of the electron transfer between recombinant cytochrome c6 (produced in high yield in Escherichia coli by coexpressing the maturation proteins encoded by the ccmA-H gene cluster) and the recombinant soluble CuA domain (i.e., the donor binding and electron entry site) of subunit II of cytochrome c oxidase from Synechocystis PCC 6803. The forward and the reverse electron transfer reactions were studied by the stopped-flow technique and yielded apparent bimolecular rate constants of (3.3 +/- 0.3) x 10(5) M(-1) s(-1) and (3.9 +/- 0.1) x 10(6) M(-1) s(-1), respectively, in 5 mM potassium phosphate buffer, pH 7, containing 20 mM potassium chloride and 25 degrees C. This corresponds to an equilibrium constant Keq of 0.085 in the physiological direction (DeltarG'0 = 6.1 kJ/mol). The reduction of the CuA fragment by cytochrome c6 is almost independent on ionic strength, which is in contrast to the reaction of the CuA domain with horse heart cytochrome c, which decreases with increasing ionic strength. The findings are discussed with respect to the potential role of cytochrome c6 as mobile electron carrier in both cyanobacterial electron transport pathways.     

C-terminal truncation and histidine-tagging of cytochrome c oxidase subunit II reveals the native processing site, shows involvement of the C-terminus in cytochrome c binding, and improves the assay for proton pumping

To enable metal affinity purification of cytochrome c oxidase reconstituted into phospholipid vesicles, a histidine-tag was engineered onto the C-terminal end of the Rhodobacter sphaeroides cytochrome c oxidase subunit II. Characterization of the natively processed wildtype oxidase and artificially processed forms (truncated with and without a his-tag) reveals Km values for cytochrome c that are 6-14-fold higher for the truncated and his-tagged forms than for the wildtype. This lowered ability to bind cytochrome c indicates a previously undetected role for the C-terminus in cytochrome c binding and is mimicked by reduced affinity for an FPLC anion exchange column. The elution profiles and kinetics indicate that the removal of 16 amino acids from the C-terminus, predicted from the known processing site of the Paracoccus denitrificans oxidase, does not produce the same enzyme as the native processing reaction. MALDI-TOF MS data show the true C-terminus of subunit II is at serine 290, three amino acids longer than expected. When the his-tagged form is reconstituted into lipid vesicles and further purified by metal affinity chromatography, significant improvement is observed in proton pumping analysis by the stopped-flow method. The improved kinetic results are attributed to a homogeneous, correctly oriented vesicle population with higher activity and less buffering from extraneous lipids.     

Definition of the interaction domain for cytochrome c on cytochrome c oxidase. I. Biochemical, spectral, and kinetic characterization of surface mutants in subunit ii of Rhodobacter sphaeroides cytochrome aa(3)

To determine the interaction site for cytochrome c (Cc) on cytochrome c oxidase (CcO), a number of conserved carboxyl residues in subunit II of Rhodobacter sphaeroides CcO were mutated to neutral forms. A highly conserved tryptophan, Trp(143), was also mutated to phenylalanine and alanine. Spectroscopic and metal analyses of the surface carboxyl mutants revealed no overall structural changes. The double mutants D188Q/E189N and D151Q/E152N exhibit similar steady-state kinetic behavior as wild-type oxidase with horse Cc and R. sphaeroides Cc(2), showing that these residues are not involved in Cc binding. The single mutants E148Q, E157Q, D195N, and D214N have decreased activities and increased K(m) values, indicating they contribute to the Cc:CcO interface. However, their reactions with horse and R. sphaeroides Cc are different, as expected from the different distribution of surface lysines on these cytochromes c. Mutations at Trp(143) severely inhibit activity without changing the K(m) for Cc or disturbing the adjacent Cu(A) center. From these data, we identify a Cc binding area on CcO with Trp(143) and Asp(214) close to the site of electron transfer and Glu(148), Glu(157), and Asp(195) providing electrostatic guidance. The results are completely consistent with time-resolved kinetic measurements (Wang, K., Zhen, Y., Sadoski, R., Grinnell, S., Geren, L., Ferguson-Miller, S., Durham, B., and Millett, F. (1999) J. Biol. Chem. 274, 38042-38050) and computational docking analysis (Roberts, V. A., and Pique, M. E. (1999) J. Biol. Chem. 274, 38051-38060).     

Kinetic characterization of the interaction between cytochrome oxidase and cytochrome c

The mechanism of electron transfer catalyzed by cytochrome oxidase was investigated by monitoring the reaction of cytochrome oxidase with cytochrome c under carefully controlled anaerobic conditions. The kinetics of the reaction were examined by varying conditions of ionic strength, inhibitor binding, and oxidation-reduction potential. An analogue of cytochrome c in which the iron atom was replaced with cobalt was used to probe the effect of redox potential on the reaction. Under conditions of low ionic strength, there is very rapid oxidation of cytochrome c and reduction of oxidase which occurs at a rate of 3 X 10(7) M-1 s-1. The number of electrons transferred exhibit a hyperbolic dependence on the concentration of cytochrome c reaching a maximum of 2 electrons transferred at the highest concentration of reduced cytochrome c employed. The total number of electrons transferred was always observed to be distributed equally between cytochrome a and a second acceptor which appears to be the associated copper center; electron transfer to cytochrome a3 did not occur in the absence of oxygen. Substitution of cytochrome c by the cobalt analogue (which represents a decrease in oxidation-reduction potential of about 400 mV) yielded identical results indicating that the origin of the lack of reactivity of cytochrome a3 is of a kinetic nature. The effect of increasing the ionic strength on the reaction was 2-fold: a marked decrease in reaction rate and the appearance of biphasic kinetics with the amplitude of the very fast absorbance changes at 605 nm decreasing from 80% to 40% of the total anticipated from static absorbance measurements. Each of the two phases accounted for a maximum of 1 electron at the highest ionic strength employed. These results are simulated in terms of a sample kinetic reaction scheme involving a two-step electron transfer at one binding site.     

Soluble CuA domain of cyanobacterial cytochrome c oxidase

The genomes of several cyanobacteria show the existence of gene clusters encoding subunits I, II, and III of aa(3)-type cytochrome c oxidase. The enzyme occurs on both plasma and thylakoid membranes of these oxygenic phototrophic prokaryotes. Here we report the expression and purification of a truncated subunit II copper A (Cu(A)) domain (i.e. the electron entry and donor binding site) of cytochrome c oxidase from the cyanobacterium Synechocystis PCC 6803 in high yield. The water-soluble purple redox-active bimetallic center displays a relatively low standard reduction potential of 216 mV. Its absorption spectrum at pH 7 is similar to that of other soluble fragments from aa(3)-type oxidases, but the insensitivity of both absorbance and circular dichroism spectra to pH suggests that it is less exposed to the aqueous milieu compared with other Cu(A) domains. Oxidation of horse heart cytochrome c by the bimetallic center follows monophasic kinetics. At pH 7 and low ionic strength the bimolecular rate constant is (2.1 +/- 0.3) x 10(4) m-1 s(-1), and the rates decrease upon the increase of ionic strength. Sequence alignment and modeling of cyanobacterial Cu(A) domains show several peculiarities such as: (i) a large insertion located between the second transmembrane region and the putative hydrophobic cytochrome c docking site, (ii) the lack of acidic residues shown to be important in the interaction between cytochrome c and Paracoccus Cu(A) domain, and (iii) an extended C terminus similar to Escherichia coli ubiquinol oxidase.     

Mutations in the docking site for cytochrome c on the Paracoccus heme aa3 oxidase. Electron entry and kinetic phases of the reaction.

Introducing site-directed mutations in surface-exposed residues of subunit II of the heme aa3 cytochrome c oxidase of Paracoccus denitrificans, we analyze the kinetic parameters of electron transfer from reduced horse heart cytochrome c. Specifically we address the following issues: (a) which residues on oxidase contribute to the docking site for cytochrome c, (b) is an aromatic side chain required for electron entry from cytochrome c, and (c) what is the molecular basis for the previously observed biphasic reaction kinetics. From our data we conclude that tryptophan 121 on subunit II is the sole entry point for electrons on their way to the CuA center and that its precise spatial arrangement, but not its aromatic nature, is a prerequisite for efficient electron transfer. With different reaction partners and experimental conditions, biphasicity can always be induced and is critically dependent on the ionic strength during the reaction. For an alternative explanation to account for this phenomenon, we find no evidence for a second cytochrome c binding site on oxidase.     

Electron transfer kinetics of soluble fragments indicate a direct interaction between complex III and the caa3 oxidase in Thermus thermophilus

The extremely thermophilic bacterium Thermus thermophilus expresses an aerobic respiratory chain resembling that of mitochondria and many mesophilic prokaryotes. Yet, interaction modes between redox partners differ between the thermophilic and mesophilic electron transport chains. While electron transfer in mesophilic organisms such as Paracoccus denitrificans follows a two-step mechanism mostly governed by long-range electrostatic interactions, the electron transfer in thermophiles is mediated mainly by apolar interactions. The terminal branch of the electron path from the bc-complex via the soluble cytochrome c(552) to the ba(3) oxidase has extensively been characterized, whereas contradicting evidence has been put forward on the nature of the physiological substrate(s) of the caa(3) oxidase. We have cloned and expressed a soluble fragment of the hydrophilic cytochrome c domain derived from subunit IIc of the caa(3) oxidase (c(caa)(3)) and characterized its kinetic behaviour in terms of substrate specificity and ionic strength dependency using pre-steady state stopped-flow techniques. The kinetics revealed fast electron transfer between the caa(3) fragment and both, the cytochrome c(552) and the soluble cytochrome c(bc) fragment of the bc-complex, showing only a weak ionic strength dependence. These data suggest a direct intercomplex electron transfer between the bc-complex and the caa(3) oxidase without requirement for a soluble electron shuttle.     

Kinetics of electron transfer between plastocyanin and the soluble CuA domain of cyanobacterial cytochrome c oxidase

It has been shown that efficient functioning of photosynthesis and respiration in the cyanobacterium Synechocystis PCC 6803 requires the presence of either cytochrome c6 or plastocyanin. In order to check whether the blue copper protein plastocyanin can act as electron donor to cytochrome c oxidase, we investigated the intermolecular electron transfer kinetics between plastocyanin and the soluble CuA domain (i.e. the donor binding and electron entry site) of subunit II of the aa3-type cytochrome c oxidase from Synechocystis. Both copper proteins were expressed heterologously in Escherichia coli. The forward and the reverse electron transfer reactions were studied yielding apparent bimolecular rate constants of (5.1+/-0.2) x 10(4) M(-1) s(-1) and (8.5+/-0.4) x 10(5) M(-1) s(-1), respectively (20 mM phosphate buffer, pH 7). This corresponds to an apparent equilibrium constant of 0.06 in the physiological direction (reduction of CuA), which is similar to Keq values calculated for the reaction between c-type cytochromes and the soluble fragments of other CuA domains. The potential physiological role of plastocyanin in cyanobacterial respiration is discussed.     

Kinetics of cytochrome c and TMPD oxidation by cytochrome c oxidase from the thermophilic bacterium, PS3

Cytochrome caa3 (cytochrome oxidase) from the thermophilic bacterium PS3 can exhibit full catalytic activity in the presence of ascorbate and TMPD or other electron donors and in the absence of added soluble c-type cytochromes. It appears to possess only a low-affinity and not a high-affinity site for the soluble cytochromes. Proteoliposomal cytochrome caa3 develops an effective membrane potential in the presence of ascorbate and TMPD or PMS, in the absence of added soluble cytochrome c. Reduction of the a3 centre is blocked in the presence of cyanide. During reductive titrations of the cyanide-inhibited enzyme, electrons initially equilibrate among three centres, the c haem, the a haem and one of the associated Cu atoms. During steady-state turnover, electrons probably enter the complex via the bound c haem; the a haem and perhaps an associated CuA atom are reduced next. It is concluded that, despite its size and hydrophobic association with the aa3 complex, the haem c-containing subunit can behave in an analogous way to that of mammalian cytochrome c, bound at the high-affinity site of the eucaryotic enzyme.     

Kinetics of the interaction of the cytochrome c oxidase of Paracoccus denitrificans with its own and bovine cytochrome c

We have devised a relatively simple method for the purification of cytochrome aa3 of Paracoccus denitrificans with three major subunits similar to those of the larger subunits of the mitochondrial cytochrome oxidase. This preparation has no c-type cytochrome. Studies were made of the oxidation of soluble cytochromes c from bovine heart and Paracoccus. The cytochrome-c oxidase activity was stimulated by low concentrations of either cytochrome c, providing an explanation for the multiphasic nature of plots of v/S versus v. Kinetics of the oxidation of bovine cytochrome c by the Paracoccus oxidase resembled those of bovine oxidase with bovine cytochrome c in every way; the Paracoccus oxidase with bovine cytochrome c can serve as an appropriate model for the mitochondrial system. The kinetics of the oxidation of the soluble Paracoccus cytochrome c by the Paracoccus oxidase were different from those seen with bovine cytochrome c, but resembled the latter if poly(L-lysine) was added to the assays. The important difference between the two species of cytochrome c is the more highly negative hemisphere on the side of the molecule way from the heme crevice in the Paracoccus cytochrome. Thus, the data emphasize the importance of all of the charged groups on cytochrome c in influencing the binding or electron transfer reactions of this oxidation-reduction system. The data also permit some interesting connotations about the possible evolution from the bacterial to the mitochondrial electron transport system.     

Electron transfer kinetics between soluble modules of Paracoccus denitrificans cytochrome c1 and its physiological redox partners

The transient electron transfer (ET) interactions between cytochrome c1 of the bc1-complex from Paracoccus denitrificans and its physiological redox partners cytochrome c552 and cytochrome c550 have been characterized functionally by stopped-flow spectroscopy. Two different soluble fragments of cytochrome c1 were generated and used together with a soluble cytochrome c552 module as a model system for interprotein ET reactions. Both c1 fragments lack the membrane anchor; the c1 core fragment (c1CF) consists of only the hydrophilic heme-carrying domain, whereas the c1 acidic fragment (c1AF) additionally contains the acidic domain unique to P. denitrificans. In order to determine the ionic strength dependencies of the ET rate constants, an optimized stopped-flow protocol was developed to overcome problems of spectral overlap, heme autoxidation and the prevalent non-pseudo first order conditions. Cytochrome c1 reveals fast bimolecular rate constants (10(7) to 10(8) M(-1) s(-1)) for the ET reaction with its physiological substrates c552 and c550, thus approaching the limit of a diffusion-controlled process, with 2 to 3 effective charges of opposite sign contributing to these interactions. No direct involvement of the N-terminal acidic c1-domain in electrostatically attracting its substrates could be detected. However, a slight preference for cytochrome c550 over c552 reacting with cyochrome c1 was found and attributed to the different functions of both cytochromes in the respiratory chain of P. denitrificans.