Probing why trypanosomes assemble atypical cytochrome c with an AxxCH haem-binding motif instead of CxxCH.

Mitochondrial cytochromes c and c1 are core components of the respiratory chain of all oxygen-respiring eukaryotes. These proteins contain haem, covalently bound to the polypeptide in a catalysed post-translational modification. In all eukaryotes, except members of the protist phylum Euglenozoa, haem attachment is to the cysteine residues of a CxxCH haem-binding motif. In the Euglenozoa, which include medically relevant trypanosomatid parasites, haem attachment is to a single cysteine residue in an AxxCH haem-binding motif. Moreover, genes encoding known c-type cytochrome biogenesis machineries are all absent from trypanosomatid genomes, indicating the presence of a novel biosynthetic apparatus. In the present study, we investigate expression and maturation of cytochrome c with a typical CxxCH haem-binding motif in the trypanosomatids Crithidia fasciculata and Trypanosoma brucei. Haem became attached to both cysteine residues of the haem-binding motif, indicating that, in contrast with previous hypotheses, nothing prevents formation of a CxxCH cytochrome c in euglenozoan mitochondria. The cytochrome variant was also able to replace the function of wild-type cytochrome c in T. brucei. However, the haem attachment to protein was not via the stereospecifically conserved linkage universally observed in natural c-type cytochromes, suggesting that the trypanosome cytochrome c biogenesis machinery recognized and processed only the wild-type single-cysteine haem-binding motif. Moreover, the presence of the CxxCH cytochrome c resulted in a fitness cost in respiration. The level of cytochrome c biogenesis in trypanosomatids was also found to be limited, with the cells operating at close to maximum capacity.

The mitochondrial cytochrome c N-terminal region is critical for maturation by holocytochrome c synthase.

The covalent attachment of heme to mitochondrial cytochrome c is catalysed by holocytochrome c synthase (HCCS, also called heme lyase). How HCCS functions and recognises the substrate apocytochrome is unknown. Here we have examined HCCS recognition of a chimeric substrate comprising a short mitochondrial cytochrome c N-terminal region with the C-terminal sequence, including the CXXCH heme-binding motif, of a bacterial cytochrome c that is not otherwise processed by HCCS. Heme attachment to the chimera demonstrates the importance of the N-terminal region of the cytochrome. A series of variants of a mitochondrial cytochrome c with amino acid replacements in the N-terminal region have narrowed down the specificity determinants, providing insight into HCCS substrate recognition.

Observation of fast release of NO from ferrous d1 haem allows formulation of a unified reaction mechanism for cytochrome cd1 nitrite reductases.

Cytochrome cd1 nitrite reductase is a haem-containing enzyme responsible for the reduction of nitrite into NO, a key step in the anaerobic respiratory process of denitrification. The active site of cytochrome cd1 contains the unique d1 haem cofactor, from which NO must be released. In general, reduced haems bind NO tightly relative to oxidized haems. In the present paper, we present experimental evidence that the reduced d1 haem of cytochrome cd1 from Paracoccus pantotrophus releases NO rapidly (k=65-200 s(-1)); this result suggests that NO release is the rate-limiting step of the catalytic cycle (turnover number=72 s(-1)). We also demonstrate, using a complex of the d1 haem and apomyoglobin, that the rapid dissociation of NO is largely controlled by the d1 haem cofactor itself. We present a reaction mechanism proposed to be applicable to all cytochromes cd1 and conclude that the d1 haem has evolved to have low affinity for NO, as compared with other ferrous haems.

Structure of a trypanosomatid mitochondrial cytochrome c with heme attached via only one thioether bond and implications for the substrate recognition requirements of heme lyase.

The principal physiological role of mitochondrial cytochrome c is electron transfer during oxidative phosphorylation. c-Type cytochromes are almost always characterized by covalent attachment of heme to protein through two thioether bonds between the heme vinyl groups and the thiols of cysteine residues in a Cys-Xxx-Xxx-Cys-His motif. Uniquely, however, members of the evolutionarily divergent protist phylum Euglenozoa, which includes Trypanosoma and Leishmania species, have mitochondrial cytochromes c with heme attached through only one thioether bond [to an (A/F)XXCH motif]; the implications of this for the cytochrome structures are unclear. Here we present the 1.55 A resolution X-ray crystal structure of cytochrome c from the trypanosomatid Crithidia fasciculata. Despite the fundamental difference in heme attachment and in the cytochrome c biogenesis machinery of the Euglenozoa, the structure is remarkably similar to that of typical (CXXCH) mitochondrial cytochromes c, both in overall fold and, other than the missing thioether bond, in the details of the heme attachment. Notably, this similarity includes the stereochemistry of the covalent heme attachment to the protein. The structure has implications for the maturation of c-type cytochromes in the Euglenozoa; it also hints at a distinctive redox environment in the mitochondrial intermembrane space of trypanosomes. Surprisingly, Saccharomyces cerevisiae cytochrome c heme lyase (the yeast cytochrome c biogenesis system) cannot efficiently mature Trypanosoma brucei cytochrome c or a CXXCH variant when expressed in the cytoplasm of Escherichia coli, despite their great structural similarity to yeast cytochrome c, suggesting that heme lyase requires specific recognition features in the apocytochrome.

Very early reaction intermediates detected by microsecond time scale kinetics of cytochrome cd1-catalyzed reduction of nitrite.

Paracoccus pantotrophus cytochrome cd(1) is a nitrite reductase found in the periplasm of many denitrifying bacteria. It catalyzes the reduction of nitrite to nitric oxide during the denitrification part of the biological nitrogen cycle. Previous studies of early millisecond intermediates in the nitrite reduction reaction have shown, by comparison with pH 7.0, that at the optimum pH, approximately pH 6, the earliest intermediates were lost in the dead time of the instrument. Access to early time points (approximately 100 micros) through use of an ultra-rapid mixing device has identified a spectroscopically novel intermediate, assigned as the Michaelis complex, formed from reaction of fully reduced enzyme with nitrite. Spectroscopic observation of the subsequent transformation of this species has provided data that demand reappraisal of the general belief that the two subunits of the enzyme function independently.

Unexpected dependence on pH of NO release from Paracoccus pantotrophus cytochrome cd1.

A previous study of nitrite reduction by Paracoccus pantotrophus cytochrome cd(1) at pH 7.0 identified early reaction intermediates. The c-heme rapidly oxidised and nitrite was reduced to NO at the d(1)-heme. A slower equilibration of electrons followed, forming a stable complex assigned as 55% cFe(III)d(1)Fe(II)-NO and 45% cFe(II)d(1)Fe(II)-NO(+). No catalytically competent NO release was observed. Here we show that at pH 6.0, a significant proportion of the enzyme undergoes turnover and releases NO. An early intermediate, which was previously overlooked, is also identified; enzyme immediately following product release is a candidate. However, even at pH 6.0 a considerable fraction of the enzyme remains bound to NO so another component is required for full product release. The kinetically stable product formed at the end of the reaction differs significantly at pH 6.0 and 7.0, as does its rate of formation; thus the reaction is critically dependent on pH.

Pseudoazurin dramatically enhances the reaction profile of nitrite reduction by Paracoccus pantotrophus cytochrome cd1 and facilitates release of product nitric oxide.

Cytochrome cd(1) is a respiratory nitrite reductase found in the periplasm of denitrifying bacteria. When fully reduced Paracoccus pantotrophus cytochrome cd(1) is mixed with nitrite in a stopped-flow apparatus in the absence of excess reductant, a kinetically stable complex of enzyme and product forms, assigned as a mixture of cFe(II) d(1)Fe(II)-NO(+) and cFe(III) d(1)Fe(II)-NO (cd(1)-X). However, in order for the enzyme to achieve steady-state turnover, product (NO) release must occur. In this work, we have investigated the effect of a physiological electron donor to cytochrome cd(1), the copper protein pseudoazurin, on the mechanism of nitrite reduction by the enzyme. Our data clearly show that initially oxidized pseudoazurin causes rapid further turnover by the enzyme to give a final product that we assign as all-ferric cytochrome cd(1) with nitrite bound to the d(1) heme (i.e. from which NO had dissociated). Pseudoazurin catalyzed this effect even when present at only one-tenth the stoichiometry of cytochrome cd(1). In contrast, redox-inert zinc pseudoazurin did not affect cd(1)-X, indicating a crucial role for electron movement between monomers or individual enzyme dimers rather than simply a protein-protein interaction. Furthermore, formation of cd(1)-X was, remarkably, accelerated by the presence of pseudoazurin, such that it occurred at a rate consistent with cd(1)-X being an intermediate in the catalytic cycle. It is clear that cytochrome cd(1) functions significantly differently in the presence of its two substrates, nitrite and electron donor protein, than in the presence of nitrite alone.