Cytochrome c2 mutants of Rhodobacter capsulatus

Demonstration of short-lived complexes of cytochrome c with cytochrome bc1 by EPR spectroscopy: implications for the mechanism of interprotein electron transfer

One of the steps of a common pathway for biological energy conversion involves electron transfer between cytochrome c and cytochrome bc1. To clarify the mechanism of this reaction, we examined the structural association of those two proteins using the electron transfer-independent electron paramagnetic resonance (EPR) techniques. Drawing on the differences in the continuous wave EPR spectra and saturation recoveries of spin-labeled bacterial and mitochondrial cytochromes c recorded in the absence and presence of bacterial cytochrome bc1, we have exposed a time scale of dynamic equilibrium between the bound and the free state of cytochrome c at various ionic strengths. Our data show a successive decrease of the bound cytochrome c fraction as the ionic strength increases, with a limit of approximately 120 mm NaCl above which essentially no bound cytochrome c can be detected by EPR. This limit does not apply to all of the interactions of cytochrome c with cytochrome bc1 because the cytochrome bc1 enzymatic activity remained high over a much wider range of ionic strengths. We concluded that EPR monitors just the tightly bound state of the association and that an averaged lifetime of this state decreases from over 100 micros at low ionic strength to less than 400 ns at an ionic strength above 120 mm. This suggests that at physiological ionic strength, the tightly bound complex on average lasts less than the time needed for a single electron exchange between hemes c and c1, indicating that productive electron transfer requires several collisions of the two molecules. This is consistent with an early idea of diffusion-coupled reactions that link the soluble electron carriers with the membranous complexes, which, we believe, provides a robust means of regulating electron flow through these complexes.

A functional hybrid between the cytochrome bc1 complex and its physiological membrane-anchored electron acceptor cytochrome cy in Rhodobacter capsulatus

The membrane integral ubihydroquinone (QH2): cytochrome (cyt) c oxidoreductase (or the cyt bc1 complex) and its physiological electron acceptor, the membrane-anchored cytochrome cy (cyt cy), are discrete components of photosynthetic and respiratory electron transport chains of purple non-sulfur, facultative phototrophic bacteria of Rhodobacter species. In Rhodobacter capsulatus, it has been observed previously that, depending on the growth condition, absence of the cyt bc1 complex is often correlated with a similar lack of cyt cy (Jenney, F. E., et al. (1994) Biochemistry 33, 2496-2502), as if these two membrane integral components form a non-transient larger structure. To probe whether such a structural super complex can exist in photosynthetic or respiratory membranes, we attempted to genetically fuse cyt cy to the cyt bc1 complex. Here, we report successful production, and initial characterization, of a functional cyt bc1-cy fusion complex that supports photosynthetic growth of an appropriate R. capsulatus mutant strain. The three-subunit cyt bc1-cy fusion complex has an unprecedented bis-heme cyt c1-cy subunit instead of the native mono-heme cyt c1, is efficiently matured and assembled, and can sustain cyclic electron transfer in situ. The remarkable ability of R. capsulatus cells to produce a cyt bc1-cy fusion complex supports the notion that structural super complexes between photosynthetic or respiratory components occur to ensure efficient cellular energy production.

Light-dependent regulation of photosynthesis genes in Rhodobacter sphaeroides 2.4.1 is coordinately controlled by photosynthetic electron transport via the PrrBA two-component system and the photoreceptor AppA

Formation of the photosynthetic apparatus in Rhodobacter is regulated by oxygen tension and light intensity. Here we show that in anaerobically grown Rhodobacter cells a light-dependent increase in expression of the puc and puf operons encoding structural proteins of the photosynthetic complexes requires an active photosynthetic electron transport. The redox-sensitive CrtJ/PpsR repressor of photosynthesis genes, which was suggested to mediate electron transport-dependent signals, is not involved in this light-dependent signal chain. Our data reveal that the signal initiated in the photosynthetic reaction centre is transmitted via components of the electron transport chain and the PrrB/PrrA two-component system in Rhodobacter sphaeroides. Under blue light illumination in the absence of oxygen this signal leads to activation of photosynthesis genes and interferes with a blue-light repression mediated by the AppA photoreceptor and the PpsR transcriptional repressor in R. sphaeroides. Thus, light either sensed by a photoreceptor or initiating photosynthetic electron transport has opposite effects on the transcription of photosynthesis genes. Both signalling pathways involve redox-dependent steps that finally determine the effect of light on gene expression.

Characterization of the interaction of Rhodobacter capsulatus cytochrome c peroxidase with charge reversal mutants of cytochrome c(2)

Steady-state kinetics for the reaction of Rhodobacter capsulatus bacterial cytochrome c peroxidase (BCCP) with its substrate cytochrome c(2) were investigated. The Rb. capsulatus BCCP is dependent on calcium for activation as previously shown for the Pseudomonas aeruginosa BCCP and Paracoccus denitrificans enzymes. Furthermore, the activity shows a bell-shaped pH dependence with optimum at pH 7.0. Enzyme activity is greatest at low ionic strength and drops off steeply as ionic strength increases, resulting in an apparent interaction domain charge product of -13. All cytochromes c(2) show an asymmetric distribution of surface charge, with a concentration of 14 positive charges near the exposed heme edge of Rb. capsulatus c(2) which potentially may interact with approximately 6 negative charges, localized near the edge of the high-potential heme of the Rb. capsulatus BCCP. To test this proposal, we constructed charge reversal mutants of the 14 positively charged residues located on the front face of Rb. capsulatus cytochrome c(2) and examined their effect on steady-state kinetics with BCCP. Mutated residues in Rb. capsulatus cytochrome c(2) that showed the greatest effects on binding and enzyme activity are K12E, K14E, K54E, K84E, K93E, and K99E, which is consistent with the site of electron transfer being located at the heme edge. We conclude that a combination of long-range, nonspecific electrostatic interactions as well as localized salt bridges between, e.g., cytochrome c(2) K12, K14, K54, and K99 with BCCP D194, D241, and D6, account for the observed kinetics.

Protein dynamics: imidazole and 2-mercaptoethanol binding to the Rhodobacter capsulatus cytochrome c(2) mutant, glycine 95 proline

The Class I c-type cytochromes can bind exogenous ligands in the oxidized state, with the kinetics of ligand binding providing information on naturally occurring intramolecular dynamics. Typically, nitrogenous bases are used as ligands; however, it is less well known that 2-mercaptoethanol (BME), a commonly used cytochrome reducing agent, can form a complex with the heme. To better understand the cytochrome-mercaptan interaction, we have investigated the kinetics of binding of BME to wild type and mutants of Rhodobacter capsulatus cytochrome c(2) and to horse cytochrome c. Complex formation with the G95P mutant is apparent from the formation of a green color and a shift in the Soret peak to 418 nm from 410 nm upon addition of BME. Unlike horse cytochrome c and wild-type R. capsulatus cytochrome c(2), G95P permits the kinetics of formation of the BME-G95P complex to be measured since complex formation and reduction kinetics can be resolved. The affinity constant for the binding of BME to mutant G95P was strong ( approximately 1.5 x 10(5)M(-1)) and the kinetics of formation of the BME-G95P complex were found to undergo a change in rate-limiting step consistent with a concentration-independent protein rearrangement (68s(-1)) followed by second-order binding of BME ( approximately approximately 1.3 x 10(5)M(-1)s(-1)). The most remarkable characteristic of mutant G95P is the relatively large amount of high-spin species in equilibrium with the low- spin form, which can be estimated to be approximately 3% at pH 7. The BME binding kinetics, coupled with the kinetics of imidazole binding to G95P, allow us, for the first time, to specify all four rate constants describing the ligand binding reaction. Moreover, we can use the kinetic results to estimate the rate constants for ligand binding with the wild-type cytochrome c(2). This has also allowed us to quantify and more fully interpret cytochrome dynamics.

Mobile cytochrome c2 and membrane-anchored cytochrome cy are both efficient electron donors to the cbb3- and aa3-type cytochrome c oxidases during respiratory growth of Rhodobacter sphaeroides

We have recently established that the facultative phototrophic bacterium Rhodobacter sphaeroides, like the closely related Rhodobacter capsulatus species, contains both the previously characterized mobile electron carrier cytochrome c2 (cyt c2) and the more recently discovered membrane-anchored cyt cy. However, R. sphaeroides cyt cy, unlike that of R. capsulatus, is unable to function as an efficient electron carrier between the photochemical reaction center and the cyt bc1 complex during photosynthetic growth. Nonetheless, R. sphaeroides cyt cy can act at least in R. capsulatus as an electron carrier between the cyt bc1 complex and the cbb3-type cyt c oxidase (cbb3-Cox) to support respiratory growth. Since R. sphaeroides harbors both a cbb3-Cox and an aa3-type cyt c oxidase (aa3-Cox), we examined whether R. sphaeroides cyt cy can act as an electron carrier to either or both of these respiratory terminal oxidases. R. sphaeroides mutants which lacked either cyt c2 or cyt cy and either the aa3-Cox or the cbb3-Cox were obtained. These double mutants contained linear respiratory electron transport pathways between the cyt bc1 complex and the cyt c oxidases. They were characterized with respect to growth phenotypes, contents of a-, b-, and c-type cytochromes, cyt c oxidase activities, and kinetics of electron transfer mediated by cyt c2 or cyt cy. The findings demonstrated that both cyt c2 and cyt cy are able to carry electrons efficiently from the cyt bc1 complex to either the cbb3-Cox or the aa3-Cox. Thus, no dedicated electron carrier for either of the cyt c oxidases is present in R. sphaeroides. However, under semiaerobic growth conditions, a larger portion of the electron flow out of the cyt bc1 complex appears to be mediated via the cyt c2-to-cbb3-Cox and cyt cy-to-cbb3-Cox subbranches. The presence of multiple electron carriers and cyt c oxidases with different properties that can operate concurrently reveals that the respiratory electron transport pathways of R. sphaeroides are more complex than those of R. capsulatus.

Redox-related conformational changes in Rhodobacter capsulatus cytochrome c2

WEFT-NOESY and transfer WEFT-NOESY NMR spectra were used to determine the heme proton assignments for Rhodobacter capsulatus ferricytochrome c2. The Fermi contact and pseudo-contact contributions to the paramagnetic effect of the unpaired electron in the oxidized state were evaluated for the heme and ligand protons. The chemical shift assignments for the 1H and 15N NMR spectra were obtained by a combination of 1H-1H and 1H-15N two-dimensional NMR spectroscopy. The short-range nuclear Overhauser effect (NOE) data are consistent with the view that the secondary structure for the oxidized state of this protein closely approximates that of the reduced form, but with redox-related conformational changes between the two redox states. To understand the decrease in stability of the oxidized state of this cytochrome c2 compared to the reduced form, the structural difference between the two redox states were analyzed by the differences in the NOE intensities, pseudo-contact shifts and the hydrogen-deuterium exchange rates of the amide protons. We find that the major difference between redox states, although subtle, involve heme protein interactions, orientation of the heme ligands, differences in hydrogen bond networks and, possible alterations in the position of some internal water molecules. Thus, it appears that the general destabilization of cytochrome c2, which occurs on oxidation, is consistent with the alteration of hydrogen bonds that result in changes in the internal dynamics of the protein.

The membrane-attached electron carrier cytochrome cy from Rhodobacter sphaeroides is functional in respiratory but not in photosynthetic electron transfer

Rhodobacter species are useful model organisms for studying the structure and function of c type cytochromes (Cyt c), which are ubiquitous electron carriers with essential functions in cellular energy and signal transduction. Among these species, Rhodobacter capsulatus has a periplasmic Cyt c2Rc and a membrane-bound bipartite Cyt cyRc. These electron carriers participate in both respiratory and photosynthetic electron-transfer chains. On the other hand, until recently, Rhodobacter sphaeroides was thought to have only one of these two cytochromes, the soluble Cyt c2Rs. Recent work indicated that this species has a gene, cycYRs, that is highly homologous to cycYRc, and in the work presented here, functional properties of its gene product (Cyt cyRs) are defined. It was found that Cyt cyRs is unable to participate in photosynthetic electron transfer, although it is active in respiratory electron transfer, unlike its R. capsulatus counterpart, Cyt cyRc. Chimeric constructs have shown that the photosynthetic incapability of Cyt cyRs is caused, at least in part, by its redox active subdomain, which carries the covalently bound heme. It, therefore, seems that this domain interacts differently with distinct redox partners, like the photochemical reaction center and the Cyt c oxidase, and allows the bacteria to funnel electrons efficiently to various destinations under different growth conditions. These findings raise an intriguing evolutionary issue in regard to cellular apoptosis: why do the mitochondria of higher organisms, unlike their bacterial ancestors, use only one soluble electron carrier in their respiratory electron-transport chains?

On the role of high-potential iron-sulfur proteins and cytochromes in the respiratory chain of two facultative phototrophs

The capability of high potential iron-sulfur proteins (HiPIPs) and soluble cytochromes to shuttle electrons between the bc1 complex and the terminal oxidase in aerobically grown cells of Rhodoferax fermentans and Rhodospirillum salinarum, two facultative phototrophs, was evaluated. In Rs. salinarum, HiPIP and a c-type cytochrome (alpha-band at 550 nm, Em,7=+290 mV) are both involved in the electron transfer step from the bc1 complex to the terminal oxidase. Kinetic studies indicate that cytochrome c550 is more efficient than HiPIP in oxidizing the bc1 complex, and that HiPIP is a more efficient reductant of the terminal oxidase as compared to cytochrome c550. Rs. salinarum cells contain an additional c-type cytochrome (asymmetric alpha-band at 556 nm, Em,7=+180 mV) which is able to reduce the terminal oxidase, but unable to oxidize the bc1 complex. c-type cytochromes could not be isolated from Rf. fermentans, in which HiPIP, the most abundant soluble electron carrier, is reduced by the bc1 complex (zero-order kinetics) and oxidized by the terminal oxidase (first-order kinetics), respectively. These data, taken together, indicate for the first time that HiPIPs play a significant role in bacterial respiratory electron transfer.

Cloning and expression in Escherichia coli of the cytochrome c552 gene from Thermus thermophilus HB8. Evidence for genetic linkage to an ATP-binding cassette protein and initial characterization of the cycA gene products

We report sequence of Thermus thermophilus HB8 DNA containing the gene (cycA) for cytochrome c552 and a gene (cycB) encoding a protein homologous with one subunit of an ATP-binding cassette transporter. The cycA gene encodes a 17-residue N-terminal signal peptide with following amino acid sequence identical to that reported by (Titani, K., Ericsson, L. H., Hon-nami, K., and Miyazawa, T. (1985) Biochem. Biophys. Res. Commun. 128, 781-787). A modified cycA was placed under control of the T7 promoter and expressed in Escherichia coli. Protein identical to that predicted from the gene sequence was found in two heme C-containing fractions. Fraction rC552, characterized by an alpha-band at 552 nm, contains approximately 60-70% of a protein highly similar to native cytochrome c552 and approximately 30-40% of a protein that contains a modified heme. Cytochrome rC552 is monomeric and is an excellent substrate for cytochrome ba3. Cytochrome rC557 is characterized by an alpha-band at 557 nm, contains approximately 90% heme C and approximately 10% of non-C heme, exists primarily as a homodimer, and is essentially inactive as a substrate for cytochrome ba3. We suggest that rC557 is a "conformational isomer" of rC552 having non-native, axial ligands to the heme iron and an "incorrect" protein fold that is stabilized by homodimer formation.

Cytochrome c(y) of Rhodobacter capsulatus is attached to the cytoplasmic membrane by an uncleaved signal sequence-like anchor

During the photosynthetic growth of Rhodobacter capsulatus, electrons are conveyed from the cytochrome (cyt) bc1 complex to the photochemical reaction center by either the periplasmic cyt c2 or the membrane-bound cyt c(y). Cyt c(y) is a member of a recently established subclass of bipartite c-type cytochromes consisting of an amino (N)-terminal domain functioning as a membrane anchor and a carboxyl (C)-terminal domain homologous to cyt c of various sources. Structural homologs of cyt c(y) have now been found in several bacterial species, including Rhodobacter sphaeroides. In this work, a C-terminally epitope-tagged and functional derivative of R. capsulatus cyt c(y) was purified from intracytoplasmic membranes to homogeneity. Analyses of isolated cyt c(y) indicated that its spectral and thermodynamic properties are very similar to those of other c-type cytochromes, in particular to those from bacterial and plant mitochondrial sources. Amino acid sequence determination for purified cyt c(y) revealed that its signal sequence-like N-terminal portion is uncleaved; hence, it is anchored to the membrane. To demonstrate that the N-terminal domain of cyt c(y) is indeed its membrane anchor, this sequence was fused to the N terminus of cyt c2. The resulting hybrid cyt c (MA-c2) remained membrane bound and was able to support photosynthetic growth of R. capsulatus in the absence of the cyt c(y) and c2. Therefore, cyt c2 can support cyclic electron transfer during photosynthetic growth in either a freely diffusible or a membrane-anchored form. These findings should now allow for the first time the comparison of electron transfer properties of a given electron carrier when it is anchored to the membrane or is freely diffusible in the periplasm.

Rhodobacter capsulatus CycH: a bipartite gene product with pleiotropic effects on the biogenesis of structurally different c-type cytochromes

While searching for components of the soluble electron carrier (cytochrome c2)-independent photosynthetic (Ps) growth pathway in Rhodobacter capsulatus, a Ps- mutant (FJM13) was isolated from a Ps+ cytochrome c2-strain. This mutant could be complemented to Ps+ growth by cycA encoding the soluble cytochrome c2 but was unable to produce several c-type cytochromes. Only cytochrome c1 of the cytochrome bc1 complex was present in FJM13 cells grown on enriched medium, while cells grown on minimal medium contained at various levels all c-type cytochromes, including the membrane-bound electron carrier cytochrome cy. Complementation of FJM13 by a chromosomal library lacking cycA yielded a DNA fragment which also complemented a previously described Ps- mutant, MT113, known to lack all c-type cytochromes. Deletion and DNA sequence analyses revealed an open reading frame homologous to cycH, involved in cytochrome c biogenesis. The cycH gene product (CycH) is predicted to be a bipartite protein with membrane-associated amino-terminal (CycH1) and periplasmic carboxyl-terminal (CycH2) subdomains. Mutations eliminating CyCH drastically decrease the production or all known c-type cytochromes. However, mutations truncating only its CycH2 subdomain always produce cytochrome c1 and affect the presence of other cytochromes to different degrees in a growth medium-dependent manner. Thus, the subdomain CycH1 is sufficient for the proper maturation of cytochrome c1 which is the only known c-type cytochrome anchored to the cytoplasmic membrane by its carboxyl terminus, while CycH2 is required for efficient biogenesis of other c-type cytochromes. These findings demonstrate that the two subdomains of CycH play different roles in the biogenesis of topologically distinct c-type cytochromes and reconcile the apparently conflicting data previously obtained for other species.

An optimized g-tensor for Rhodobacter capsulatus cytochrome c2 in solution: a structural comparison of the reduced and oxidized states

The optimized g-tensor parameters for the oxidized form of Rhodobacter capsulatus cytochrome c2 in solution were obtained using a set (50) of backbone amide protons. Dipolar shifts for more than 500 individual protons of R. capsulatus cytochrome c2 have been calculated by using the optimized g-tensor and the X-ray crystallographic coordinates of the reduced form of R. capsulatus cytochrome c2. The calculated results for dipolar shifts are compared with the observed paramagnetic shifts. The calculated and the observed data are in good agreement throughout the entire protein, but there are significant differences between calculated and experimental results localized to the regions in the immediate vicinity of the heme ligand and the region of the front crevice of the protein (residues 44-50, 53-57, and 61-68). The results not only indicate that the overall solution structures are very similar in both the reduced and oxidized states, but that these structures in solution are similar to the crystal structure. However, there are small structural changes near the heme and the rearrangement of certain residues that result in changes in their hydrogen bonding concomitant with the change in the oxidation states; this was also evident in the data for the NH exchange rate measurements for R. capsulatus cytochrome c2.

Investigation of oxidation state-dependent conformational changes in Desulfovibrio vulgaris Hildenborough cytochrome c553 by two-dimensional H-NMR spectra

Two-dimensional nuclear magnetic resonance spectroscopy (2D-NMR) was used to assign the proton resonances of ferricytochrome C553 from Desulfovibrio vulgaris Hildenborough. The spin systems of 76 out of 79 amino acids were identified by J-correlation spectroscopy (COSY and HOHAHA) in H20 and D20 and correlated by nuclear Overhauser effect spectroscopy (NOESY). The proton chemical shifts are compared in both oxidized and reduced states of the protein at 23 degrees C and pH 5.9. Chemical shift variations between reduced and oxidized states are due to the paramagnetic contribution. Medium and long-range nOe demonstrate the lack of major changes between the two redox states. NMR data provide evidence that in this low oxidoreduction potential cytochrome, the oxidized state is more rigid than the reduced state.

The membrane-bound cytochrome cy of Rhodobacter capsulatus can serve as an electron donor to the photosynthetic reaction of Rhodobacter sphaeroides

Rhodobacter capsulatus has two different pathways for reduction of the photo-oxidized reaction center, one using water-soluble cytochrome c2, the other via membrane-associated cytochrome cy. Rhodobacter sphaeroides differs in that it lacks a cytochrome cy homologue capable of functioning in photosynthetic electron transfer; cytochrome c2 is thus the sole electron carrier, and is required for photosynthetic (Ps+) growth. Genetic evidence indicates that cytochrome cy of R. capsulatus can complement a Ps- cytochrome-c2-deficient mutant of R sphaeroides (Jenny, F.E. and Daldal, F (1993). EMBO J. 12, 1283-1292). Here, we show that it transfers electrons from cytochrome bc1 complex to the reaction center in R. sphaeroides, albeit at a lower rate than that catalyzed by the endogenous cytochrome c2. When cytochrome cy is expressed in R. sphaeroides in the presence of cytochrome c2, there is an increase in the amount of photo-oxidizable c-type cytochrome. In the absence of cytochrome c2, electron transfer via cytochrome cy shows significantly different kinetics for reaction center reduction and cytochrome c oxidation. These findings further establish that cytochrome cy, the electron carrier permitting soluble cytochrome c2-independent photosynthetic growth in R. capsulatus, can function in a similar capacity in R. sphaeroides.

Stability study of Rhodobacter capsulatus ferrocytochrome c2 wild-type and site-directed mutants using hydrogen/deuterium exchange monitored by electrospray ionization mass spectrometry

To estimate the stability of Rhodobacter capsulatus ferrocytochrome c2 wild-type and site-directed mutants, charge state distributions and hydrogen/deuterium exchange rates were monitored by electrospray ionization mass spectrometry. The relative stability of the mutants was observed with the order: V11 insert > Y75F > wild-type = K32E > K12D = K14E > or = K52E > K14E/K32E > W67Y > P35A > I57N > G34S. (A preliminary account has been presented for mutants G34S and P35A [Jaquinod et al. (1995) Rapid Commun. Mass Spectrom. 9, 1135-1140].) This approach is shown to be a useful tool for rapid characterization of mutational effects on protein conformation.

Assignment of the 13C and 13CO resonances for Rhodobacter capsulatus ferrocytochrome c2 using double-resonance and triple-resonance NMR spectroscopy

Rhodobacter capsulatus cytochrome c2 uniformly labelled with 13C/15N has been prepared. The 13C resonances of the reduced state, including those of the carbonyl and heme 13C, have been assigned using a combination of various two- and three-dimensional correlated NMR experiments. Assignment of the sidechain 13C resonances facilitated correction of a small number of previously misassigned sidechain 1H and led to the additional assignment of 32 1H. It was found that 13C alpha and 13CO secondary shifts were better indicators of secondary structure than 1H alpha and 13C beta secondary shifts. Moreover, it was demonstrated that, despite the significant ring current effects present in heme proteins, 13C alpha and 13CO secondary shifts can be employed to accurately identify secondary structure in heme proteins, independently of NOE experiments.

Strategies for the study of cytochrome c structure and function by site-directed mutagenesis

The class I cytochromes c have been extensively studied by biochemical and biophysical methods; however, many questions remain concerning the roles of specific amino acids in electron transfer and stability properties. The method of site-directed mutagenesis, which substitutes specific amino acid residues by genetic methods, is ideal for addressing these questions of cytochrome c structure and function. Practical considerations of mutational effects on protein processing and stability will be addressed. The criteria for the selection of mutation sites will be discussed. Examples of site-directed mutagenesis studies, which were designed to elucidate the factors controlling biological electron transfer, protein processing, and protein stability, are given.

The interaction between cytochrome c2 and the cytochrome bc1 complex in the photosynthetic purple bacteria Rhodobacter capsulatus and Rhodopseudomonas viridis

The rates of electron transfer from a ubiquinol analogue to cytochrome c2 catalyzed by the cytochrome bc1 complexes of Rhodobacter capsulatus and Rhodopseudomonas viridis were measured as a function of ionic strength. The effects of ionic strength on the kinetic parameters for the reactions are consistent with a role for electrostatic complex formation between cytochrome c2 and the cytochrome bc1 complex in the electron-transfer pathways in both photosynthetic purple non-sulfur bacteria. Additional support for a docking model in which positively charged lysines on cytochrome c2 interact with negatively charged groups on the Rb. capsulatus cytochrome bc1 complex was obtained from kinetic experiments using Rb. capsulatus cytochrome c2 and equine cytochrome c in which specific lysine residues were altered by site-directed mutagenesis and chemical modification, respectively. Equine cytochrome c, which is a poor electron donor to the reaction center of Rps. viridis, is an effective electron acceptor for the Rps. viridis cytochrome bc1 complex. Chemical modification of lysine residues on Rps. viridis cytochrome c2 has a substantially greater effect on the reduction of the Rps. viridis reaction center by ferrocytochrome c2 than on the oxidation of the Rps. viridis cytochrome bc1 complex by ferricytochrome c2. These data suggest that the docking site for Rps. viridis cytochrome c2 on the Rps. viridis reaction center tetraheme subunit differs in structure from the docking site for the cytochrome on the Rps. viridis cytochrome bc1 complex to a significant extent. In this respect, Rps. viridis differs from photosynthetic purple non-sulfur bacteria in which the reaction center does not contain a tetraheme subunit, where the binding sites for cytochrome c2 on the reaction center and the cytochrome bc1 complex appear to be quite similar.