Effect of enzymatic methylation of yeast iso-1-cytochrome c on its isoelectric point

Yeast iso-1- unmethylated and methylated apocytochrome c were synthesized in vitro by translating yeast cytochrome c mRNA, and by subsequently methylating the protein product. Unmethylated and methylated iso-1-holocytochrome c were extracted from Saccharomyces cerevisiae. By employing a column isoelectrofocusing technique, the pI values of these proteins were determined. The pI values of unmethylated and methylated apocytochrome c were found to be 9.60 and 8.70, respectively, with a difference of 0.90 pI unit. On the other hand, the pI values of unmethylated and methylated holocytochrome c were 9.72 and 9.68, respectively, with a difference of 0.04 unit. Therefore, although the pI values of both apo- and holocytochrome c decreased by methylation, methylation of apocytochrome c had a more profound effect on the pI of the protein. The result also indicated that conjugation of heme to apocytochrome c increased its pI value, resulting in the more "compact" and basic structure of the protein. The observed magnitude of the pI change subsequent to the methylation of apocytochrome c (decrease of 0.90 unit) seemed to be contradictory to the predicted increase in the value, since the positive charge is fixed on the quaternary amino group of trimethyllysine and there is no proton to titrate. Trimethylation of epsilon-NH2 group of Res-72 lysine of apocytochrome c could disrupt any possible hydrogen bond formed by the nitrogen atom of Res-72 lysine residues, as visualized by a space-filling model. The model and observed shift in the "effective charge" of the protein strongly suggest that conformational change in the apoprotein takes place upon methylation. This presumably altered conformation along with the decrease in pI caused by methylation may play a role in enhancement of apocytochrome c import into mitochondria.     

Deeply branching c6-like cytochromes of cyanobacteria

The cyanobacterium Synechococcus sp. PCC 7002 carries two genes, petJ1 and petJ2, for proteins related to soluble, cytochrome c6 electron transfer proteins. PetJ1 was purified from the cyanobacterium, and both cytochromes were expressed with heme incorporation in Escherichia coli. The expressed PetJ1 displayed spectral and biochemical properties virtually identical to those of PetJ1 from Synechococcus. PetJ1 is a typical cytochrome c6 but contains an unusual KDGSKSL insertion. PetJ2 isolated from E. coli exhibited absorbance spectra characteristic of cytochromes, although the alpha, beta, and gamma bands were red-shifted relative to those of PetJ1. Moreover, the surface electrostatic properties and redox midpoint potential of PetJ2 (pI 9.7; E(m,7) = 148 +/- 1.7 mV) differed substantially from those of PetJ1 (pI 3.8; E(m,7) = 319 +/- 1.6 mV). These data indicate that the PetJ2 cytochrome could not effectively replace PetJ1 as an electron acceptor for the cytochrome bf complex in photosynthesis. Phylogenetic comparisons against plant, algal, bacterial, and cyanobacterial genomes revealed two novel and widely distributed clusters of previously uncharacterized, cyanobacterial c 6-like cytochromes. PetJ2 belongs to a group that is distinct from both c6 cytochromes and the enigmatic chloroplast c 6A cytochromes. We tentatively designate the PetJ2 group as c6C cytochromes and the other new group as c6B cytochromes. Possible functions of these cytochromes are discussed.     

Cytochrome f from spinach and cyanobacteria. Purification and characterization

Cytochrome f has been purified from spinach chloroplasts and from the photosynthetic membranes of the cyanobacterium Spirulina maxima. The spinach protein has an isoelectric point of 5.2 and gives a single band on isoelectric focusing gels. The S. maxima cytochrome shows a major band with a pI of 4.01 and a minor band with a pI of 3.97. S. maxima cytochrome f has a molecular weight approximately 38,000 and is monomeric, while the spinach protein is slightly smaller, approximately 36,000 daltons, and aggregates to form an octamer. S. maxima cytochrome f has an E'0 of +339 mV which is close to that of cytochromes f from higher plants. The NH2-terminal amino acid sequences of the cytochromes show striking similarities. Spinach cytochrome f shows a clear preference for oxidation by spinach plastocyanin and S. maxima cytochrome f is more readily oxidized by its in vivo reaction partner, cytochrome c553.     

The interaction between methanol dehydrogenase and the autoreducible cytochromes c of the facultative methylotroph Pseudomonas AM1.

Cytochromes cH and cL were autoreduced at high pH (pK greater than 10) and the autoreduced cytochromes reacted with CO. The autoreduction was first-order with respect to oxidized cytochrome c and was reversible by lowering the pH. Pure methanol dehydrogenase reduced cytochrome c (in the absence of methanol) by lowering the pK for autoreduction to less than 8.5. A mechanism is proposed for the autoreduction of cytochrome c and its involvement in the reaction with methanol dehydrogenase.     

The contribution of electrostatic factors to the stabilization of the conformation of cytochrome c. Studies on the maleylated protein.

All the lysines of horse heart cytochrome c were maleylated yielding a low spin product. At room temperature and low salt concentration, this product lacked the 695 nm absorption band and showed tryptophan fluorescence and circular dichroic spectra typical of denatured cytochrome c. The 695 nm band and the native tryptophan fluorescence and circular dichroic spectra were restored by addition of salts, their effectiveness being dependent on the charge of the cation. On low salt concentration, the 695 nm band was also restored by lowering the temperature. Studies of the temperature dependence of the 695 nm band indicate that the thermal denaturation of maleylated cytochrome c occurs at temperatures 60-70 degrees C lower than in the native protein. This implies a destabilization of the native conformation by 5.6 kcal/mol; a similar value is evidenced by comparative urea denaturation studies on the native and modified proteins. The results confirm the assumption that the native conformation of cytochrome c is mostly determined by interactions involving internal residues.     

Two types of cytochrome cd1 in the aerobic photosynthetic bacterium, Erythrobacter sp. OCh 114

Components I and II of cytochrome cd1 which had different spectral features were purified from the aerobic photosynthetic bacterium, Erythrobacter sp. strain OCh 114. Component I showed an absorption maxima at 700 and 406 nm in the oxidized form, and at 621, 552.5, 548 and 416 nm in the reduced form. Component II showed an absorption maxima at 635 and 410 nm in the oxidized form and at 628, 552.5, 548 and 417 nm in the reduced form. The relative molecular mass, Mr, of both cytochromes was determined to be 135,000 with two identical subunits. Components I and II showed pI values of 7.6 and 6.8, respectively. The redox potential of hemes ranged from +234 mV to +242 mV, except for the heme d1 of component I (Em7 = +134 mV). Components I and II showed both cytochrome c oxidase and nitrite reductase activities. Cytochrome c oxidase activity was strongly inhibited by a low concentration of nitrite and cyanide. Erythrobacter cytochromes c-551 and c-552 were utilized as electron donors for the cytochrome c oxidase reaction. The high affinity of cytochrome c-552 to component II (Km = 1.27 microM) suggested a physiological significance for this cytochrome. Erythrobacter cytochromes cd1 are unique in their presence in cells grown under aerobic conditions as compared to other bacterial cytochromes cd1 which are formed only under denitrifying conditions.     

Crystal structure of oxidized Bacillus pasteurii cytochrome c553 at 0.97-A resolution

This article reports the first X-ray structure of the soluble form of a c-type cytochrome isolated from a Gram-positive bacterium. Bacillus pasteurii cytochrome c(553), characterized by a low reduction potential and by a low sequence homology with cytochromes from Gram-negative bacteria or eukaryotes, is a useful case study for understanding the structure-function relationships for this class of electron-transfer proteins. Diffraction data on a single crystal of cytochrome c(553) were obtained using synchrotron radiation at 100 K. The structure was determined at 0.97-A resolution using ab initio phasing and independently at 1.70 A in an MAD experiment. In both experiments, the structure solution exploited the presence of a single Fe atom as anomalous scatterer in the protein. For the 0.97-A data, the phasing was based on a single data set. This is the most precise structure of a heme protein to date. The crystallized cytochrome c(553) contains only 71 of the 92 residues expected from the intact protein sequence, lacking the first 21 amino acids at the N-terminus. This feature is consistent with previous evidence that this tail, responsible for anchoring the protein to the cytoplasm membrane, is easily cleaved off during the purification procedure. The heme prosthetic group in B. pasteurii cytochrome c(553) is surrounded by three alpha-helices in a compact arrangement. The largely exposed c-type heme group features a His-Met axial coordination of the Fe(III) ion. The protein is characterized by a very asymmetric charge distribution, with the exposed heme edge located on a surface patch devoid of net charges. A structural search of a representative set of protein structures reveals that B. pasteurii cytochrome c(553) is most similar to Pseudomonas cytochromes c(551), followed by cytochromes c(6), Desulfovibrio cytochrome c(553), cytochromes c(552) from thermophiles, and cytochromes c from eukaryotes. Notwithstanding a low sequence homology, a structure-based alignment of these cytochromes shows conservation of three helical regions, with different additional secondary structure motifs characterizing each protein. In B. pasteurii cytochrome c(553), these motifs are represented by the shortest interhelix connecting fragments observed for this group of proteins. The possible relationships between heme solvent accessibility and the electrochemical reduction potential are discussed.     

Ubiquinol-cytochrome c oxidoreductase of higher plants. Isolation and characterization of the bc1 complex from potato tuber mitochondria.

A procedure is described for isolation of active ubiquinol-cytochrome c oxidoreductase (bc1 complex) from potato tuber mitochondria using dodecyl maltoside extraction and ion exchange chromatography. The same procedure works well with mitochondria from red beet and sweet potato. The potato complex has at least 10 subunits resolvable by gel electrophoresis in the presence of dodecyl sulfate. The fifth subunit carries covalently bound heme. The two largest ("core") subunits either show heterogeneity or include a third subunit. The purified complex contains about 4 mumol of cytochrome c1, 8 mumol of cytochrome b, and 20 mumol of iron/g of protein. The complex is highly delipidated, with 1-6 mol of phospholipid and about 0.2 mol of ubiquinone/mol of cytochrome c1. Nonetheless it catalyzes electron transfer from a short chain ubiquinol analog to equine cytochrome c with a turnover number of 50-170 mol of cytochrome c reduced per mol of cytochrome c1 per s, as compared with approximately 220 in whole mitochondria. The enzymatic activity is stable for weeks at 4 degrees C in phosphate buffer and for months at -20 degrees C in 50% glycerol. The activity is inhibited by antimycin, myxothiazol, and funiculosin. The complex is more resistant to funiculosin and diuron than the beef heart enzyme. The optical difference spectra of the cytochromes were resolved by analysis of full-spectrum redox titrations. The alpha-band absorption maxima are 552 nm (cytochrome c1), 560 nm (cytochrome b-560), and 557.5 + 565.5 nm (cytochrome b-566, which has a split alpha-band). Extinction coefficients appropriate for the potato cytochromes are estimated. Despite the low lipid and ubiquinone content of the purified complex, the midpoint potentials of the cytochromes (257, 51, and -77 mV for cytochromes c1, b-560, and b-566, respectively) are not very different from values reported for whole mitochondria. EPR spectroscopy shows the presence of a Rieske-type iron sulfur center, and the absence of centers associated with succinate and NADH dehydrogenases. The complex shows characteristics associated with a Q-cycle mechanism of redox-driven proton translocation, including two pathways for reduction of b cytochromes by quinols and oxidant-induced reduction of b cytochromes in the presence of antimycin.     

Soluble cytochromes and a photoactive yellow protein isolated from the moderately halophilic purple phototrophic bacterium, Rhodospirillum salexigens

Three soluble cytochromes were found in two strains of the halophilic non-sulfur purple bacterium Rhodospirillum salexigens. These are cytochromes C2, C and c-551. Cytochrome C2 was recognized by the presence of positive charge at the site of electron transfer (measured by laser flash photolysis), although the protein has an overall negative charge (pI = 4.7). Cytochrome C2 has a high redox potential (300 mV) and is monomeric (13 kDa). Cytochrome c was recognized from its characteristic absorption spectrum. It has a redox potential of 95 mV, an isoelectric point of 4.3, and is isolated as a dimer (33 kDa) of identical subunits (14 kDa), a property which is typical of this family of proteins. R. salexigens cytochrome c-551 has an absorption spectrum similar to the low redox potential Rb. sphaeroides cytochrome c-551.5. It also has a low redox potential (-170 mV), is very acidic (pI = 4.5), and is monomeric (9 kDa), apparently containing 1 heme per protein. The existence of abundant membrane-bound cytochromes c-558 and c-551 which are approximately half reduced by ascorbate and completely reduced by dithionite suggests the presence of a tetraheme reaction center cytochrome in R. salexigens, although reaction centers purified in a previous study (Wacker et al., Biochim. Biophys. Acta (1988) 933, 299-305) did not contain a cytochrome. The most interesting observation is that R. salexigens contains a photoactive yellow protein (PYP), previously observed only in the extremely halophilic purple sulfur bacterium Ectothiorhodospira halophila. The R. salexigens PYP appears to be slightly larger than that of Ec. halophila (16 kDa vs. 14 kDa). Otherwise, these two yellow proteins have similar absorption spectra, chromatographic properties and kinetics of photobleaching and recovery.     

The cytochrome c oxidase-cytochrome c complex: spectroscopic analysis of conformational changes in the protein-protein interaction domain

Binding to cytochrome c oxidase induces a conformational change in the cytochrome c molecule. This conformational change has been characterized by comparing the binding of native cytochrome c and chemically modified cytochrome c derivatives to bovine cytochrome c oxidase by using absorption, circular dichroism (CD), and magnetic circular dichroism (MCD) spectroscopy. The following derivatives were analyzed: (i) cytochrome c modified at all 19 lysine residues to yield the (N epsilon-acetimidyl)19 cytochrome c, (N epsilon-isopropyl)19 cytochrome c, and (N epsilon,N epsilon-dimethyl)19 cytochrome c; (ii) cytochrome c in which Met65 and Met80 are converted to the methionine sulfoxide; (iii) cytochrome c with a single break in the polypeptide chain at Arg38 or Gly37. The derivatives bind to cytochrome c oxidase at a ratio of one heme c per heme aa3. The association constants are similar to that of native cytochrome c except for (N epsilon-isopropyl)19 and (N epsilon,N epsilon-dimethyl)19 cytochromes c, which bind respectively four times and six times less strongly. The derivatives are good substrates for the cytochrome c oxidase reaction. The spectral changes accompanying the binding of the modified cytochromes c to cytochrome c oxidase are quite different from the spectral changes observed with native cytochrome c. The different optical absorption and MCD changes are explained by a polarity change around the exposed heme edge in the cytochrome c-cytochrome c oxidase complex. The CD changes indicate a conformational rearrangement restricted to the surface area surrounding the exposed heme edge. The rearrangement may involve a movement of the evolutionarily conserved Phe82 out of the vicinity of the heme.(ABSTRACT TRUNCATED AT 250 WORDS)     

Purification and characterization of two soluble cytochromes from the alkalophile Bacillus firmus RAB

A soluble cytochrome c and soluble cytochrome b were purified from the alkalophilic Bacillus firmus RAB. The cytochrome c, with an alpha band at 552 nm, had an apparent molecular weight of 16,500 and was acidic, with a pI of 3.4. At both pH 7.0 and 8.3, the midpoint potential of c-552 was +66 mV. Above pH 8.3, the cytochrome exhibited a pH-dependent decrease in midpoint potential. This property, among others, distinguished the cytochrome c-552 from other membrane-associated c-type cytochromes. The soluble cytochrome b, with an alpha band maximum at 558 nm, had a molecular weight of approx. 15,500 and was also an acidic protein, with a pI of 3.07. It exhibited a pH-independent midpoint potential of +28 mV.     

Methionine-80-sulfoxide cytochrome c: preparation, purification and electron-transfer capabilities

In order to explore the electron-transferring properties of methionine-80-sulfoxide cytochrome c, the pure, chromatographically homogeneous methionine-80-sulfoxide cytochrome c was previously published procedure (Ivanetich, K.M., Bradshaw, J.J. and Kaminsky, L.S. (1976) Biochemistry 15, 1144-1153) was found to produce a mixture of products. In the pure derivative, visible spectroscopy indicates that the 695 nm band indicative of the Met-80-Fe coordination is missing, amino acid analysis indicates that only one methionine is modified to the sulfoxide, and the E0' is found to be 240 mV vs. N.H.E. For succinate cytochrome c reductase activity, the Km for modified cytochrome was about one-ninth that of the native protein, while the maximum turnover number of the reductase with the modified protein was only about 54% of that with native protein. In contrast, the activity with cytochrome oxidase measured polarographically using ascorbate and TMPD under two different buffer/pH conditions, gave Km values that were very similar for both the native and modified cytochromes c, but the maximum turnover numbers of the oxidase with the modified protein were less than 40% of native in either buffer. It is concluded that the Met-80-sulfoxide cytochrome c in the reduced form is able to maintain substantially its heme crevice structure and thus maintain Km values similar to those of native protein. However, the low maximum turnover numbers for oxidase activity with the modified protein in the reduced state indicate that electron transfer itself has been significantly decreased, probably because the parity of acid/base and electrostatic interactions of Met-80 sulfur with the Fe in the two redox states has been disrupted.     

Low-temperature studies of electron transfer between different cytochromes c and cytochrome c oxidase.

The ability of various native and modified cytochromes c to transfer electrons to cytochrome oxidase is compared in cytochrome c depleted beef heart mitochondrial particles. The kinetics are followed at -49 degrees C after the reaction is initiated by photolysis of the CO compound of cytochrome oxidase in the presence of oxygen. Horse, human, yeast iso-2, and carboxydinitrophenyl (CDNP)-lysine-60 horse cytochromes c all give initial rates of electron transfer that are equal to those observed in whole beef mitochondria. Euglena, CDNP-lysine-72, and CDNP-lysine-13 horse cytochromes c give rates about one-tenth that of whole mitochondria. These rates were independent of the concentration of cytochrome c. Since the inhibited cytochromes c, but not the active proteins, had previously been shown to have lowered affinity for cytochrome oxidase, the results indicate that the structural characteristics important for the association of cytochrome c and oxidase are also essential for achieving normal rates of electron transfer within the complex once formed.     

Cytochrome and Ubiquinone Patterns During Growth of Azotobacter vinelandii

After synthesis during the early log phase, the concentrations of ubiquinone and cytochromes did not vary during the growth cycle of Azotobacter vinelandii, when grown with either high or low aeration on nitrogen-free or urea-containing media. The level of aeration had no effect on the concentrations of the electron carriers synthesized, but affected the growth rate. On urea-containing medium, the concentration of cytochrome a(2) was low, but it was synthesized at a linear rate when the bacteria were transferred to nitrogen-free medium. A. vinelandii was shown to utilize sufficient medium urea to account for all of the cell nitrogen. Growth on urea-containing medium with an oxygen atmosphere resulted in low growth yields, and cytochromes c(4) + c(5) were not synthesized; the concentrations of ubiquinone and cytochromes b(1), a(1), and a(2) were only 12 to 18% of the values for growth on nitrogen-free medium with high aeration.     

Synthesis and degradation of mitochondrial components in hypertrophied rat heart

The accumulation of inner mitochondrial components of rat heart was studied 1 and 3 days after constriction of the ascending aorta of rats. By 1 day after aortic constriction, the activities of three mitochondrial respiratory enzymes/mg of cardiac homogenate protein were increased; after 3 days, specific activities had levelled off or decreased. Selective accumulation of inner mitochondrial membrane components 24h after aortic constriction was further indicated by increased left ventricular cytochrome c concentration (nmol/mg of protein). By 3 days after surgery, cytochrome c concentration was significantly diminished. Low-temperature spectroscopy of isolated mitochondria showed that the ratios of cytochromes c, b and a+a(3) remained unchanged after aortic constriction, suggesting that cytochrome c was a good indicator of the response of the other mitochondrial inner-membrane cytochromes as well. The effect of cardiac hypertrophy on the turnover of cytochrome c was also examined. Cytochrome c was labelled in its haem group with delta-amino[2,3-(3)H(2)]laevulinate 3 days before aortic constriction. By 1 day after surgery the total ventricular radioactivity in cytochrome c of aortic banded animals was significantly higher than in sham-operated controls, indicating a decreased degradation rate in the former during the first postoperative day. delta-Aminolaevulinate was shown to be a particularly suitable precursor for such turnover studies, since it results in rapid pulse-labelling of cytochrome c (peak activity in 90min), is rapidly removed from the precursor pool (t((1/2))=30min) and is not reutilized.     

A carboxyl-terminal hydrophobic region of yeast cytochrome c1 is necessary for functional assembly into complex III of the respiratory chain

Cytochrome c1 is an amphiphilic protein which binds to the mitochondrial inner membrane, presumably through a hydrophobic region near the carboxyl (C)-terminus. In the preceding study (Hase, T., et al. (1987) J. Biochem. 102, 401-410), two cytochrome c1 mutations were constructed: delta 1 and delta 2 cytochromes c1, in which the C-terminal segments of 17 and 71 residues were replaced by foreign sequences of 20 and 15 residues, respectively. delta 2 cytochrome c1 had lost the putative membrane anchor. The two cytochrome c1 mutants were localized in mitochondria, but succinate-cytochrome c1 reductase activity was detected only in the mitochondria containing delta 1 cytochrome c1. The membrane association of the two mutant molecules as well as that of authentic cytochrome c1 was investigated. These three molecules were firmly attached to mitochondrial membranes and not solubilized on either sonication or sodium carbonate (pH 11) treatment. However, when the membranes were solubilized with Triton X-100, both the delta 1 and authentic cytochromes c1 were extracted from the membranes more easily than delta 2 cytochrome c1. By fractionating cholate extracts of mitochondrial membranes with ammonium sulfate, delta 1 cytochrome c1 was cofractionated with the enzymatic activity of complex III, but delta 2 cytochrome c1 was clearly separated from the complex III fraction. Trypsin treatment of mitochondria and mitoplasts showed that delta 2 cytochrome c1 was exposed to the intermembrane space, with such a topology that its trypsin susceptibility became much higher than that of the authentic molecule.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cytochrome c and cytochrome c oxidase interactions: the effects of ionic strength and hydrostatic pressure studied with site-specific modifications of cytochrome c.

Seven cytochromes c, in which individual lysines have been modified to the propylthiobimane derivatives, have been prepared. These derivatives were also converted to the porphyrin cytochromes c by treatment with HF. The properties of both types of modified proteins were studied in their reactions with cytochrome c oxidase. The results show that lysines 25, 27, 60, 72, and 87 do not contribute a full charge to the binding interaction with the oxidase. These five residues, with the exception of the lysine-60 derivative, on the front surface of the protein and contain the solvent-accessible edge of the heme prosthetic group. By contrast, lysines 8 and 13 at the top of the front surface do contribute a full charge to the binding interaction with the oxidase. The removal of the positive charge on any one lysine weakens the binding to cytochrome c oxidase by at least 1 kcal (1 cal = 4.1868 J). The presence of bimane at lysines 13 and 87 clearly forces the separation of the cytochrome c and oxidase, but this does not occur with the other complexes. The bimane-modified lysine-13 protein, and to a lesser extent that modified at lysine 8, show the interesting effect of enhanced complex formation with cytochrome c oxidase when subjected to pressure, possibly because of entrapment of water at the newly created interface of the complex. Our observations indicate that the two proteins of the cytochrome c - cytochrome oxidase complex have preferred, but not obligatory, spatial orientations and that interaction occurs without either protein losing significant portions of its hydration shell.     

The conformation of eukaryotic cytochrome c around residues 39, 57, 59 and 74.

1H-n.m.r. studies of horse, tuna, Candida krusei and Saccharomyces cerevisiae cytochromes c showed that each of the proteins contains a similar cluster of residues at the bottom of the protein that assists in shielding the haem from the solvent. The relative positions of the residues forming these clusters vary continuously with temperature, and they change with the change in protein redox state. This conformational heterogeneity is discussed with reference to the conformational flexibility of cytochrome c around residues 57, 59 and 74. Spectroscopic measurements of pKa values for Lys-55 (horse and tuna cytochromes c) and His-33 and His-39 (C. krusei and S. cerevisiae cytochromes c) are in excellent agreement with expectations based on chemical-modification studies of horse cytochrome c. [Bosshard & Zürrer (1980) J. Biol. Chem. 255, 6694-6699] and on the X-ray-crystallographic structure of tuna cytochrome c [Takano & Dickerson (1981) J. Mol. Biol. 153, 79-94, 95-115].     

Isolation and properties of the soluble c-type cytochromes of the dinoflagellate Peridinium cinctum

Four soluble cytochromes of the c type were isolated from the freshwater dinoflagellate Peridinium cinctum collected from Lake Kinneret, Israel. Cytochrome c with alpha-band maximum at 550 nm in the reduced state had a molecular mass of 10,200 Da, pI 7.4, and Em of 278 m V. This cytochrome was active in the respiratory chain of beef heart Keilin-Hartree particles. Cytochrome c-553 had a molecular mass of 13,200 Da, pI 4.9, and Em of 384 m V, and was active in light induced electron transport of Euglena gracilis chloroplast fragments. Cytochrome c-554 had a molecular mass of 13,500 Da, pI 4.4, and Em of 326 m V. This cytochrome was inactive in light induced electron transport but competed with cytochrome c-552 of Euglena in the assay. The acidic cytochrome c-557 was present in very small quantities. The properties of the soluble c-type cytochromes of P. cinctum are compatible with the classification of dinoflagellates as primitive eucaryotes.