Amino acid sequence of cytochrome c-552 from a thermophilic hydrogen-oxidizing bacterium, Hydrogenobacter thermophilus

Inversion of the stereochemistry around the sulfur atom of the axial methionine side chain through alteration of amino acid side chain packing in Hydrogenobacter thermophilus cytochrome C552 and its functional consequences

In cytochrome c, the coordination of the axial Met Sδ atom to the heme Fe atom occurs in one of two distinctly different stereochemical manners, i.e., R and S configurations, depending upon which of the two lone pairs of the Sδ atom is involved in the bond; hence, the Fe-coordinated Sδ atom becomes a chiral center. In this study, we demonstrated that an alteration of amino acid side chain packing induced by the mutation of a single amino acid residue, i.e., the A73V mutation, in Hydrogenobacter thermophilus cytochrome c552 (HT) forces the inversion of the stereochemistry around the Sδ atom from the R configuration [Travaglini-Allocatelli, C., et al. (2005) J. Biol. Chem. 280, 25729-25734] to the S configuration. Functional comparison between the wild-type HT and the A73V mutant possessing the R and S configurations as to the stereochemistry around the Sδ atom, respectively, demonstrated that the redox potential (Em) of the mutant at pH 6.00 and 25 °C exhibited a positive shift of ∼20 mV relative to that of the wild-type HT, i.e., 245 mV, in an entropic manner. Because these two proteins have similar enthalpically stabilizing interactions, the difference in the entropic contribution to the Em value between them is likely to be due to the effect of the conformational alteration of the axial Met side chain associated with the inversion of the stereochemistry around the Sδ atom due to the effect of mutation on the internal mobility of the loop bearing the axial Met. Thus, the present study demonstrated that the internal mobility of the loop bearing the axial Met, relevant to entropic control of the redox function of the protein, is affected quite sensitively by the contextual stereochemical packing of amino acid side chains in the proximity of the axial Met.

Enhancement of the thermostability of Hydrogenobacter thermophilus cytochrome c(552) through introduction of an extra methylene group into its hydrophobic protein interior

Careful scrutiny of the protein interior of Hydrogenobacter thermophilus cytochrome c(552) (HT) on the basis of its X-ray structure [Travaglini-Allocatelli, C., Gianni, S., Dubey, V. K., Borgia, A., Di Matteo, A., Bonivento, D., Cutruzzola, F., Bren, K. L., and Brunori, M. (2005) J. Biol. Chem. 280, 25729-25734] indicated that a void space, which is large enough to accommodate a methyl group, exists in the hydrophobic protein interior near the heme. We tried to reduce the void space through the replacement of a Val by Ile or Leu (Val/Ile or Val/Leu mutation), and then the structural and functional consequences of these two mutations were characterized in order to elucidate the relationship between the nature of the packing of hydrophobic residues and the functional properties of the protein. The study demonstrated striking differences in the structural and functional consequences between the two mutations. The Val/Ile mutation was found to cause further enhancement of the thermostability of the oxidized HT, as reflected in the increase of the denaturation temperature (T(m)) value by ∼ 3 deg, whereas the thermostability of the reduced form was essentially unaffected. As a result, the redox potential (E(m)) of the Val/Ile mutant exhibited a negative shift of ∼ 50 mV relative to that of the wild-type protein in an enthalpic manner, this being consistent with our previous finding that a protein with higher stability in its oxidized form exhibits a lower E(m) value [Terui, N., Tachiiri, N., Matsuo, H., Hasegawa, J., Uchiyama, S., Kobayashi, Y., Igarashi, Y., Sambongi, Y., and Yamamoto, Y. (2003) J. Am. Chem. Soc. 125, 13650-13651]. In contrast, the Val/Leu mutation led to a decrease in thermostability of both the redox forms of the protein, as reflected in the decreases of the T(m) values of the oxidized and reduced proteins by ∼ 3 and ∼ 5 deg, respectively, and the E(m) value of the Val/Leu mutant happened to be similar to that of the Val/Ile one. The E(m) value of the Val/Leu mutant could be reasonably interpreted in terms of the different effects of the mutation on the stabilities of the two different redox forms of the protein. Thus, the present study demonstrated that the stability of the protein is affected quite sensitively by the contextual stereochemical packing of hydrophobic residues in the protein interior and that the structural properties of the hydrophobic core in the protein interior are crucial for control of the redox function of the protein. These findings provide novel insights as to functional control of a protein, which could be utilized for tuning of the T(m) and E(m) values of the protein by means of protein engineering.

Characterization of N-terminal amino group–heme ligation emerging upon guanidine hydrochloric acid induced unfolding of Hydrogenobacter thermophilus ferricytochrome c 552

Nonnative heme coordination structures emerging upon guanidine hydrochloric acid (GdnHCl) induced unfolding of Hydrogenobacter thermophilus ferricytochrome c552 were characterized by means of paramagnetic NMR. The heme coordination structure possessing the N-terminal amino group of the peptide chain in place of axial Met (His-Nterm form) was determined in the presence of GdnHCl concentrations in excess of 1.5 M at neutral pH. The stability of the His-Nterm form at pH 7.0 was found to be comparable with that of the bis-His form which has been recognized as a major nonnative heme coordination structure in cytochrome c folding/unfolding. Consequently, in addition to the bis-His form, the His-Nterm form is a substantial intermediate which affects the pathway and kinetics of the folding/unfolding of cytochromes c, of which the N-terminal amino groups are not acetylated.

Local Conformational Transition of Hydrogenobacter thermophilus Cytochrome c552 Relevant to Its Redox Potential,

In order to elucidate the molecular mechanisms responsible for the apparent nonlinear behavior of the temperature dependence of the redox potential of Hydrogenobacter thermophilus cytochrome c552 [Takahashi, Y., Sasaki, H., Takayama, S. J., Mikami, S., Kawano, S., Mita, H., Sambongi, Y., and Yamamoto, Y. (2006) Biochemistry 45, 11005-11011], its heme active site structure has been characterized using variable-temperature and -pressure NMR techniques. The study revealed a temperature-dependent conformational transition between protein structures, which slightly differ in the conformation of the loop bearing the Fe-bound axial Met residue. The heme environment in the protein structure which arises at lower temperature was found to be more polar, as a result of the altered orientation of the loop with respect to the heme due to its conformational change, than that arising at higher temperature. The present study demonstrated the importance of the structural and dynamic properties of the polypeptide chain in close proximity to the heme for redox regulation of the protein.

Further enhancement of the thermostability of Hydrogenobacter thermophilus cytochrome c552

Thermophile Hydrogenobacter thermophilus cytochrome c(552) (HT) is a stable protein with denaturation temperatures (T(m)) of 109.8 and 129.7 degrees C for the oxidized and reduced forms, respectively [Uchiyama, S., Ohshima, A., Nakamura, S., Hasegawa, J., Terui, N., Takayama, S. J., Yamamoto, Y., Sambongi, Y., and Kobayashi, Y. (2004) J. Am. Chem. Soc. 126, 14684-14685]. The removal of a single hydroxyl group from the hydrophobic core of HT, through the replacement of a Tyr by Phe, resulted in further elevation of the T(m) value of the oxidized form by approximately 6 degrees C, the T(m) value of the reduced one remaining essentially unaltered. As a result, the redox potential of the mutant with higher stability in the oxidized form exhibited a negative shift of approximately 20 mV relative to that of wild-type HT in an enthalpic manner. These findings indicated that the redox function of a protein can be enthalpically regulated through the stability of the oxidized form by altering the contextual stereochemical packing of hydrophobic residues in the protein interior using protein engineering.

Cytochrome c552 Mutants: Structure and Dynamics at the Active Site Probed by Multidimensional NMR and Vibration Echo Spectroscopy

Spectrally resolved infrared stimulated vibrational echo experiments are used to measure the vibrational dephasing of a CO ligand bound to the heme cofactor in two mutated forms of the cytochrome c552 from Hydrogenobacter thermophilus. The first mutant (Ht-M61A) is characterized by a single mutation of Met61 to an Ala (Ht-M61A), while the second variant is doubly modified to have Gln64 replaced by an Asn in addition to the M61A mutation (Ht-M61A/Q64N). Multidimensional NMR experiments determined that the geometry of residue 64 in the two mutants is consistent with a non-hydrogen-bonding and hydrogen-bonding interaction with the CO ligand for Ht-M61A and Ht-M61A/Q64N, respectively. The vibrational echo experiments reveal that the shortest time scale vibrational dephasing of the CO is faster in the Ht-M61A/Q64N mutant than that in Ht-M61A. Longer time scale dynamics, measured as spectral diffusion, are unchanged by the Q64N modification. Frequency-frequency correlation functions (FFCFs) of the CO are extracted from the vibrational echo data to confirm that the dynamical difference induced by the Q64N mutation is primarily an increase in the fast (hundreds of femtoseconds) frequency fluctuations, while the slower (tens of picoseconds) dynamics are nearly unaffected. We conclude that the faster dynamics in Ht-M61A/Q64N are due to the location of Asn64, which is a hydrogen bond donor, above the heme-bound CO. A similar difference in CO ligand dynamics has been observed in the comparison of the CO derivative of myoglobin (MbCO) and its H64V variant, which is caused by the difference in axial residue interactions with the CO ligand. The results suggest a general trend for rapid ligand vibrational dynamics in the presence of a hydrogen bond donor.

Cloning, expression, crystallization and preliminary X-ray characterization of cytochrome c552 from a moderate thermophilic bacterium, Hydrogenophilus thermoluteolus

The amino-acid sequence of cytochrome c552 (PH c552) from a moderately thermophilic bacterium, Hydrogenophilus thermoluteolus, was more than 50% identical to that of cytochrome c from an extreme thermophile, Hydrogenobacter thermophilus (HT c552), and from a mesophile, Pseudomonas aeruginosa (PA c551). The PH c552 gene was overexpressed as a correctly processed holoprotein in the Escherichia coli periplasm. The overexpressed PH c552 has been crystallized by vapour diffusion from polyethylene glycol 4000 pH 6.5. The crystals belong to space group C222(1), with unit-cell parameters a = 48.98, b = 57.99, c = 56.20 A. The crystals diffract X-rays to around 2.1 A resolution.

Control of the Redox Potential of Pseudomonas aeruginosa Cytochrome c551 through the Fe−Met Coordination Bond Strength and pKa of a Buried Heme Propionic Acid Side Chain

Pseudomonas aeruginosa cytochrome c(551) and a series of its mutants exhibiting various thermostabilities have been studied by paramagnetic (1)H NMR and cyclic voltammetry in an effort to elucidate the molecular mechanisms responsible for control of the redox potentials (E degrees ') of the proteins. The study revealed that the E degrees ' value of the protein is regulated by two molecular mechanisms operating independently of each other. One is based on the Fe-Met coordination bond strength in the protein, which is determined by the amino acid side chain packing in the protein, and the other on the pK(a) of the heme 17-propionic acid side chain, which is affected by the electrostatic environment. The former mechanism alters the magnitude of the E degrees ' value throughout the entire pH range, and the latter regulates the pK values reflected by the pH profile of the E degrees ' value. These findings provide novel insights into functional regulation of the protein, which could be utilized for tuning the E degrees ' value of the protein by means of protein engineering.

Five amino acid residues responsible for the high stability of Hydrogenobacter thermophilus cytochrome c552: reciprocal mutation analysis

Five amino acid residues responsible for extreme stability have been identified in cytochrome c(552) (HT c(552)) from a thermophilic bacterium, Hydrogenobacter thermophilus. The five residues, which are spatially distributed in three regions of HT c(552), were replaced with the corresponding residues in the homologous but less stable cytochrome c(551) (PA c(551)) from Pseudomonas aeruginosa. The quintuple HT c(552) variant (A7F/M13V/Y34F/Y43E/I78V) showed the same stability against guanidine hydrochloride denaturation as that of PA c(551), suggesting that the five residues in HT c(552) necessarily and sufficiently contribute to the overall stability. In the three HT c(552) variants carrying mutations in each of the three regions, the Y34F/Y43E mutations resulted in the greatest destabilization, by -13.3 kJ mol(-1), followed by A7F/M13V (-3.3 kJ mol(-1)) and then I78V (-1.5 kJ mol(-1)). The order of destabilization in HT c(552) was the same as that of stabilization in PA c(551) with reverse mutations such as F34Y/E43Y, F7A/V13M, and V78I (13.4, 10.3, and 0.3 kJ mol(-1), respectively). The results of guanidine hydrochloride denaturation were consistent with those of thermal denaturation for the same variants. The present study established a method for reciprocal mutation analysis. The effects of side-chain contacts were experimentally evaluated by swapping the residues between the two homologous proteins that differ in stability. A comparative study of the two proteins was a useful tool for assessing the amino acid contribution to the overall stability.

Complete Thermal-Unfolding Profiles of Oxidized and Reduced Cytochromes c

The complete thermal-unfolding profiles of both oxidized and reduced forms of cytochrome c551 (PA) from mesophilic Pseudomonas aeruginosa and cytochrome c552 (HT) from thermophilic Hydrogenobacter thermophilus were obtained by the newly developed pressure-proof cell compartment installed in a circular dichroic spectrometer, which facilitates protein thermal-unfolding experiments up to 180 degrees C. The thermodynamic cycle, which relates protein stability and redox function, indicated that the redox potentials of PA and HT in the native state are regulated by the stability of the oxidized proteins rather than by that of the reduced ones.

Effects of axial methionine coordination on the in-plane asymmetry of the heme electronic structure of cytochrome c

The paramagnetic susceptibility ( chi) tensors of the oxidized forms of thermophile Hydrogenobacter thermophilus cytochrome c(552) (Ht cyt c(552)) and a quintuple mutant (F7A/V13 M/F34Y/E43Y/V78I; qm) of mesophile Pseudomonas aeruginosa cytochrome c(551) (Pa cyt c(551)) have been determined on the basis of the redox-dependent (1)H NMR shift changes of the main-chain NH and C(alpha)H proton resonances of non-coordinated amino acid residues and the NMR structures of the reduced forms of the corresponding proteins (J. Hasegawa, T. Yoshida, T. Yamazaki, Y. Sambongi, Y. Yu, Y. Igarashi, T. Kodama, K. Yamazaki, Y. Kyogoku, Y. Kobayashi (1998) Biochemistry 37:9641-9649; J. Hasegawa, S. Uchiyama, Y. Tanimoto, M. Mizutani, Y. Kobayashi, Y. Sambongi,Y. Igarashi (2000) J Biol Chem 275:37824-37828). From the chi tensors determined, we obtained the contact shifts for heme methyl proton resonances, which provided the heme electronic structures of the oxidized forms of Ht cyt c(552) and qm. We also characterized the heme electronic structure of the cyanide adducts of the proteins, where the axial Met was replaced by an exogenous cyanide ion, through the analysis of (1)H NMR spectra. The results indicated that the heme electronic structures of both the proteins in their oxidized forms with axial His and Met coordination are largely different to each other, while those in their cyanide adducts are similar to each other. These results demonstrated that the orientation of the axial Met sulfur lone pair, with respect to heme, predominantly contributes to the spin delocalization into the porphyrin-pi system of heme in the oxidized proteins with axial His and Met coordination.

Relationship between redox function and protein stability of cytochromes c

Electrochemical, 1H NMR, and optical studies on mesophile Pseudomonas aeruginosa cytochrome c551, its single (F34Y) and quintuple (F7A/V13M/F34Y/E43Y/V78I) mutants, and thermophile Hydrogenobacter thermophilus cytochrome c552 at wide temperature range demonstrated that the stable protein exhibits the low redox potential predominantly due to the enthalpic contribution to the redox reaction. The overall stability of the oxidized form was shown to determine the stability of the Fe-methionine coordination bond, which then directly regulates the redox function.

Influence of Amino Acid Side Chain Packing on Fe−Methionine Coordination in Thermostable Cytochrome c

Paramagnetic NMR and optical studies of the oxidized forms of mesophile Pseudomonas aeruginosa cytochrome c(551) and its quintuple mutant (F7A/V13M/F34Y/E43Y/V78I), and thermophile Hydrogenobacter thermophilus cytochrome c(552) demonstrated that the amino acid side chain packings in the protein interior influence the coordination bond between the heme iron and the axial methionine in the proteins. The strength of heme axial coordinations was found to correlate with the overall protein thermostability.

Cytochrome c from a thermophilic bacterium has provided insights into the mechanisms of protein maturation, folding, and stability

Cytochrome c is widely distributed in bacterial species, from mesophiles to thermophiles, and is one of the best-characterized redox proteins in terms of biogenesis, folding, structure, function, and evolution. Experimental molecular biology techniques (gene cloning and expression) have become applicable to cytochrome c, enabling its engineering and manipulation. Heterologous expression systems for cytochromes c in bacteria, for use in mutagenesis studies, have been established by extensive investigation of the biological process by which the functional structure is formed. Mutagenesis and structure analyses based on comparative studies using a thermophile Hydrogenobacter thermophilus cytochrome c-552 and its mesophilic counterpart have provided substantial clues to the mechanism underlying protein stability at the amino-acid level. The molecular mechanisms underlying protein maturation, folding, and stability in bacterial cytochromes c are beginning to be understood.

Thermodynamic characterization of variants of mesophilic cytochrome c and its thermophilic counterpart

Thermal stability was measured for variants of cytochrome c-551 (PA c-551) from a mesophile, Pseudomonas aeruginosa, and a thermophilic counterpart, Hydrogenobacter thermophilus cytochrome c-552 (HT c-552), by differential scanning calorimetry (DSC) at pH 3.6. The mutated residues in PA c-551, selected with reference to the corresponding residues in HT c-552, were located in three spatially separated regions: region I, Phe7 to Ala/Val13 to Met; region II, Glu34 to Tyr/Phe43 to Tyr; and region III, Val78 to Ile. The thermodynamic parameters determined indicated that the mutations in regions I and III caused enhanced stability through not only enthalpic but also entropic contributions, which reflected improved packing of the side chains. Meanwhile, the mutated region II made enthalpic contributions to the stability through electrostatic interactions. The obtained differences in the Gibbs free energy changes of unfolding [Delta(DeltaG)] showed that the three regions contributed to the overall stability in an additive manner. HT c-552 had the smallest heat capacity change (DeltaC(P)), resulting in higher DeltaG values over a wide temperature range (0-100 degrees C), compared to the PA c-551 variants; this contributed to the highest stability of HT c-552. Our DSC measurement results, in conjunction with mutagenesis and structural studies on the homologous mesophilic and thermophilic cytochromes c, provided an extended thermodynamic view of protein stabilization.

NMR and CD conformational studies of the C-terminal 16-peptides of Pseudomonas aeruginosa c551 and Hydrogenobacter thermophilus c552 cytochromes

The 16-amino acid sequences of the C-terminal helices of the homologous bacterial cytochromes c551 from Pseudomonas aeruginosa and C552 from Hydrogenobacter thermophilus were synthesized and their solution structure studied. Circular dichroism and NMR experiments in aqueous solution have shown the presence of alpha-helices and 3(10)-helices. The populations of helical structures in phosphate buffer, pH 3.5, 293 K, were 21% for c551 and 20% for c552, but increased to 56.7 and 48%, respectively, in 50% aqueous 2,2,2-trifluoroethanol. An isodichroic point was observed at 203 nm in CD spectra for the helix/coil transition in mixtures of water/2,2,2-trifluoroethanol. NMR spectra in phosphate buffer show the presence of both alpha- and 3(10)-helical structures. In water/2,2,2-trifluoroethanol (50:50) alpha-helices are predominant. CD temperature-dependency studies indicate that both peptides exhibit the same cooperativity for the transition in water/2,2,2-trifluoroethanol (50:50). The experimental data show that the amino acid substitutions do not favor heat resistance of the secondary structure of the c552 C-terminal helix at the local level. Instead, they optimize nonlocal contacts of the polypeptide chain, which stabilize the tertiary structure in the native protein.

Selected mutations in a mesophilic cytochrome c confer the stability of a thermophilic counterpart

Mesophilic cytochrome c(551) of Pseudomonas aeruginosa (PA c(551)) became as stable as its thermophilic counterpart, Hydrogenobacter thermophilus cytochrome c(552) (HT c(552)), through only five amino acid substitutions. The five residues, distributed in three spatially separated regions, were selected and mutated with reference to the corresponding residues in HT c(552) through careful structure comparison. Thermodynamic analysis indicated that the stability of the quintuple mutant of PA c(551) could be partly attained through an enthalpic factor. The solution structure of the mutant showed that, as in HT c(552), there were tighter side chain packings in the mutated regions. Furthermore, the mutant had an increased total accessible surface area, resulting in great negative hydration free energy. Our results provide a novel example of protein stabilization in that limited amino acid substitutions can confer the overall stability of a natural highly thermophilic protein upon a mesophilic molecule.

Stabilization of Pseudomonas aeruginosa cytochrome c(551) by systematic amino acid substitutions based on the structure of thermophilic Hydrogenobacter thermophilus cytochrome c(552)

A heterologous overexpression system for mesophilic Pseudomonas aeruginosa holocytochrome c(551) (PA c(551)) was established using Escherichia coli as a host organism. Amino acid residues were systematically substituted in three regions of PA c(551) with the corresponding residues from thermophilic Hydrogenobacter thermophilus cytochrome c(552) (HT c(552)), which has similar main chain folding to PA c(551), but is more stable to heat. Thermodynamic properties of PA c(551) with one of three single mutations (Phe-7 to Ala, Phe-34 to Tyr, or Val-78 to Ile) showed that these mutants had increased thermostability compared with that of the wild-type. Ala-7 and Ile-78 may contribute to the thermostability by tighter hydrophobic packing, which is indicated by the three dimensional structure comparison of PA c(551) with HT c(552). In the Phe-34 to Tyr mutant, the hydroxyl group of the Tyr residue and the guanidyl base of Arg-47 formed a hydrogen bond, which did not exist between the corresponding residues in HT c(552). We also found that stability of mutant proteins to denaturation by guanidine hydrochloride correlated with that against the thermal denaturation. These results and others described here suggest that significant stabilization of PA c(551) can be achieved through a few amino acid substitutions determined by molecular modeling with reference to the structure of HT c(552). The higher stability of HT c(552) may in part be attributed to some of these substitutions.

Solution structure of thermostable cytochrome c-552 from Hydrogenobacter thermophilus determined by 1H-NMR spectroscopy

The solution structure of a thermostable cytochrome c-552 from a thermophilic hydrogen oxidizing bacterium Hydrogenobacter thermophilus was determined by proton nuclear magnetic resonance spectroscopy. Twenty structures were calculated by the X-PLOR program on the basis of 902 interproton distances, 21 hydrogen bonds, and 13 torsion angle constraints. The pairwise average root-mean-square deviation for the main chain heavy atoms was 0.91 +/- 0.11 A. The main chain folding of the cytochrome c-552 was almost the same as that of Pseudomonas aeruginosa cytochrome c-551 that has 59% sequence identity to the cytochrome c-552 but is less thermostable. We found several differences in local structures between the cytochromes c-552 and c-551. In the cytochrome c-552, aromatic-amino interactions were uniquely formed between Arg 35 and Tyr 32 and/or Tyr 41, the latter also having hydrophobic contacts with the side chains of Tyr 32, Ala 38, and Leu 42. Small hydrophobic cores were more tightly packed in the cytochrome c-552 because of the occupancies of Ala 5, Met 11, and Ile 76, each substituted by Phe 7, Val 13, and Val 78, respectively, in the cytochrome c-551. Some of these structural differences may contribute to the higher thermostability of the cytochrome c-552.

Cytochromes c-552 from two strains of the hydrogenotrophic bacterium Alcaligenes eutrophus are sequence homologs of the cytochromes c8 from the denitrifying pseudomonads

Soluble cytochromes c-552 were purified from two strains of the hydrogenothrophic species Alcaligenes eutrophus and their amino acid sequences determined. The two cytochromes were found to have 5 differences out of a total of 89 residues. The proteins are clearly related to the cytochromes c8 (formerly called Pseudomonas cytochromes c-551), but require a single residue insertion after the methionine sixth heme ligand relative to the Pseudomonas aeruginosa protein. The consensus residues Trp56 and Trp77, characteristic for the c8 family, are also present in the Alcaligenes proteins. Overall, the Alcaligenes cytochromes are only 43% identical to the Pseudomonas proteins which average 68% identity to one another. They are also only 45% identical to cytochrome c8 from Hydrogenobacter thermophilus, another hydrogenothrophic species, which indicates that the hydrogen utilizing bacteria are not more closely related to one another than they are to other species. The finding of cytochrome c8 in Alcaligenes eutrophus completes the recent characterization of a cytochrome cd1-nitrite reductase from this bacterial species and suggests the existence of the same denitrification pathway as in Pseudomonas where these two proteins are reaction partners.

The distance between bacterial species in sequence space

Despite the revolution caused by information from macromolecular sequences, the basis of bacterial classification remains the genus and the species. How do these terms relate to the variety of bacteria that exist on earth? In this paper, the inter- and intraspecies differences in amino acid sequence of several bacterial electron transport proteins, cytochromes c, and blue copper proteins are compared. For the soil and water organisms studied, bacterial species can be classed as "tight" when there is little intraspecies variation, or "loose" when this variation is large. For this set of proteins and organisms, interspecies variation is much larger than that within a species. Examples of "tight" species are Pseudomonas aeruginosa and Rhodobacter sphaeroides, while Pseudomonas stutzeri and Rhodopseudomonas palustris are loose species. The results are discussed in the context of the origin and age of bacterial species, and the distribution of genomes in "sequence space." The situation is probably different for commensal or pathogenic bacteria, whose population structure and evolution are linked to the properties of another organism.

A high-potential soluble cytochrome c-551 from the purple phototrophic bacterium Chromatium vinosum is homologous to cytochrome c8 from denitrifying pseudomonads

A minor cytochrome c-551 component of Chromatium vinosum was previously found to efficiently couple electron transfer between the cytochrome bc1 complex and the photosynthetic reaction center. We have now determined the amino acid sequence of this cytochrome c-551 and find that it is homologous to cytochrome c8 (formerly called Pseudomonas cytochrome c-551). It is most similar to Methylophilus methylotrophus, Rhodocyclus tenuis, and Azotobacter vinelandii cytochromes c8 (respectively, 57%, 52% and 51%). The C. vinosum cytochrome c8 has a single residue insertion relative to Pseudomonas and Azotobacter cytochromes c8. It has fewer charged residues than its homologs and is essentially neutral, which may explain why it is less soluble than the others. The cytochromes c8 are only very distantly related to the cytochromes c2 found in other species of purple bacteria which are much larger in size and which usually mediate electron transfer between the cytochrome bc1 complex and the reaction center. The photosynthetic pathway in Chromatium thus appears to be radically different from that in purple non-sulfur bacteria.

Synthesis of holo Paracoccus denitrificans cytochrome c550 requires targeting to the periplasm whereas that of holo Hydrogenobacter thermophilus cytochrome c552 does not. Implications for c-type cytochrome biogenesis

Expression from a plasmid of the complete gene, including the codons for the N-terminal periplasmic targeting signal, for cytochrome c550 of Paracoccus denitrificans led to the formation of the holo protein in the periplasms of both P. denitrificans and Escherichia coli. Expression of the gene from which the region coding for the targeting signal had been specifically deleted resulted in formation of apo-protein in the cytoplasms of both organisms. These findings are consistent with haem attachment occurring in the periplasm. In contrast, the formation of holo cytochrome c552 from Hydrogenobacter thermophilus following expression of the gene lacking the periplasmic targeting sequence in either P. denitrificans or E. coli is attributed to spontaneous cytoplasmic attachment of haem to the thermostable protein.

Cloning, nucleotide sequence and expression of the cytochrome c-552 gene from Hydrogenobacter thermophilus

A cytochrome c-552 gene from a thermophilic hydrogen-oxidizing bacterium, Hydrogenobacter thermophilus, was cloned by using two oligonucleotide probes, which had been synthesized based on the known amino acid sequence of the protein. A 780-bp PstI-SphI fragment of the cloned DNA was sequenced and found to contain the entire structural gene coding for cytochrome c-552 bracketed by apparent Escherichia coli consensus sequences for initiation and termination of transcription. Cytochrome c-552 is synthesized in vivo as a precursor having an N-terminal signal sequence consisting of 18 amino acid residues. The cloned cytochrome c-552 gene without its own signal sequence was introduced into the pKK223-3 vector and expressed in E. coli upon induction with isopropyl beta-D-thiogalactoside. An expressed cytochrome c-552 protein had a methionine residue at the N-terminus since an initiation signal was introduced before the first amino acid residue of the mature cytochrome c-552. The heme c was attached to apo-type cytochrome c-552 in the cytoplasm of E. coli and the holoprotein had spectral properties, similar to the authentic cytochrome c-552 from H. thermophilus.

Sequence variability in bacterial cytochromes c

Cytochromes c are proteins that can be defined both phenotypically and by their possession of a characteristic sequence motif. Many sequences from bacterial sources are known, and new ones are being reported every year. An analysis can be made as to what fraction of new sequences are members of already known classes or subclasses, and how many map into previously uninhabited regions of sequence space.