Baker's yeast flavocytochrome b2 (L-(+)-lactate dehydrogenase). An immunological study of structure and function

Cloning and characterization of the lactate-specific inducible gene KlCYB2, encoding the cytochrome b(2) of Kluyveromyces lactis

In yeast the utilization of lactate requires two enzymes, the D and L-lactate ferricytochrome c oxidoreductase (D and L-LCR), which stereospecifically oxidize D- and L-lactate to pyruvate. These enzymes are nuclearly encoded and localized in mitochondria. In the yeast Kluyveromyces lactis, a mutant devoid of D- and L-LCR activities and unable to grow on racemic lactate was isolated. Transformation of the mutant with a K. lactis genomic library allowed the isolation of the KlCYB2 gene, restoring the growth on lactate and the L-LCR activity. The KlCYB2 gene and its flanking regions were sequenced (Accession No. AJ243324; EMBL/GenBank databases). The deduced amino acid sequence is highly homologous to the corresponding Saccharomyces cerevisiae and Hansenula anomala protein sequences previously characterized. The homology is missed in the N-terminal region, corresponding to the presequence cleaved during import into mitochondria. Analysis of KlCYB2 gene expression indicated that, in contrast to S. cerevisiae, the major regulatory feature is induction by lactate.

Current awareness on yeast

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Probing intramolecular electron transfer within flavocytochrome b2 with a monoclonal antibody

Flavocytochrome b2 or L-lactate dehydrogenase from yeast is a tetrameric enzyme which oxidizes lactate at the expense of cytochrome c or artificial electron acceptors. The prosthetic group FMN is reduced by the substrate and then transfers sequentially the reducing equivalents to heme b2 in the same subunit. The latter is reoxidized by cytochrome c. The crystal structure of the enzyme indicates that each subunit is composed of a flavodehydrogenase domain (FDH) and a cytochrome b2 domain; the latter, which encompasses the first 99 residues of the peptide chain, is mobile relative to the tetrameric FDH assembly. We describe here the properties of a monoclonal antibody elicited against the holoenzyme. It only recognizes the heme-binding domain, with a Kd lower than 10(-7) M, and its epitope is conformational. In the enzyme-IgG complex, flavin is reduced normally and can be reoxidized by ferricyanide, but no longer by heme b2. Stopped-flow experiments in the absence of electron acceptors give no indication of flavin to heme electron transfer in the enzyme-antibody complex. In other words, the two domains are functionally uncoupled. The binding stoichiometry is 1/1 for the Fab fragment with respect to the isolated, monomeric, heme-binding domain, but 2/4 with respect to the enzyme tetramer; furthermore, binding of two Fab fragments per tetramer is sufficient to cause inhibition of intra-subunit flavin to heme electron transfer in all four subunits. Altogether these results can only be rationalized by considering that mobility of the cytochrome domain with respect to the FDH is an essential component of the catalytic cycle. The first experiment designed to locate the epitope shows it does not encompass the interdomain peptide linker (so-called hinge region, centered on residues 99-100).

Carbon catabolite repression in Kluyveromyces lactis: isolation and characterization of the KIDLD gene encoding the mitochondrial enzyme D-lactate ferricytochrome c oxidoreductase

In the "petite-negative" yeast Kluyveromyces lactis carbon catabolite repression of some cytoplasmic enzymes has been observed. However, with respect to mitochondrial enzymes, in K. lactis, unlike the case in the "petite-positive" yeast Saccharomyces cerevisiae, growth on fermentable carbon sources does not cause repression of respiratory enzymes. In this paper data are reported on carbon catabolite repression of mitochondrial enzymes in K. lactis, in particular on L- and D-lactate ferricytochrome c oxidoreductase (LCR). The L- and D-LCR (E.C. 1123, E.C. 1124) in yeast catalyze the stereospecific oxidation of D and L isomers of lactate to pyruvate. This pathway is linked to the respiratory chain, cytochrome c being the electron acceptor of the redox reaction. We demonstrate that the level of mitochondrial D- and L-LCR is controlled by the carbon source, being induced by the substrate lactate and catabolite-repressed by glucose. We cloned the structural gene for D-LCR of K. lactis (KlDLD), by complementation of growth on D,L-lactate in the S. cerevisiae strain WWF18-3D, carrying both a CYB2 disruption and the dld mutation. From the sequence analysis an open reading frame was identified that could encode a polypeptide of 579 amino acids, corresponding to a calculated molecular weight of 63,484 Da. Analysis of mRNA expression indicated that glucose repression and induction by lactate are exerted at the transcriptional level.

The NAM1 protein (NAM1p), which is selectively required for cox1, cytb and atp6 transcript processing/stabilisation, is located in the yeast mitochondrial matrix

The NAM1 nuclear gene was shown to control the stability and/or processing of mitochondrial transcripts of the cytochrome b, cytochrome oxidase subunit I and ATP synthase subunit VI genes [Groudinsky O., Bousquet I., Wallis M. G., Slonimski, P. P. & Dujardin G. (1993) Mol. Gen. Genet. 240, 419-427]. In order to better understand the mode of action of the NAM1 gene product, we have examined its intracellular fate. A fusion plasmid enabling bacterial over-expression of the corresponding protein-A-NAM1 cognate was constructed and subsequently employed as an antigen to raise polyclonal antibodies. These antibodies specifically recognise a 50-kDa protein which purifies along with the mitochondria and corresponds to NAM1p. Submitochondrial localisation experiments show that NAM1p is a soluble protein, located interior to the mitoplasts. Matricial location is a strong argument in favour of a direct interaction of NAM1p with particular mitochondrial transcripts and leads us to propose a model in which NAM1p could be an RNA-convoying protein stabilising and directing mitochondrial transcripts towards the inner face of the inner membrane where translation and assembly seem to occur.

Isolation of the DLD gene of Saccharomyces cerevisiae encoding the mitochondrial enzyme D-lactate ferricytochrome c oxidoreductase

In Saccharomyces cerevisiae the utilization of lactate occurs via specific oxidation of L- and D-lactate to pyruvate catalysed by L-lactate ferricytochrome c oxidoreductase (L-LCR) (EC 1.1.2.3) encoded by the CYB2 gene, and D-lactate ferricytochrome c oxidoreductase (D-LCR) (EC 1.1.2.4), respectively. We selected several lactate- pyruvate+ mutants in a cyb2 genetic background. Two of them were devoid of D-LCR activity (dld mutants, belonging to the same complementation group). The mutation mapped in the structural gene. This was demonstrated by a gene dosage effect and by the thermosensitivity of the enzyme activity of thermosensitive revertants. The DLD gene was cloned by complementation for growth on D-, L-lactate in the strain WWF18-3D, carrying both a CYB2 disruption and the dld mutation. The minimal complete complementing sequence was localized by subcloning experiments. From the sequence analysis an open reading frame (ORF) was identified that could encode a polypeptide of 576 amino-acids, corresponding to a calculated molecular weight of 64000 Da. The deduced protein sequence showed significant homology with the previously described microsomal flavoprotein L-gulono-gamma-lactone oxidase isolated from Rattus norvegicus, which catalyses the terminal step of L-ascorbic acid biosynthesis. These results are discussed together with the role of L-LCR and D-LCR in lactate metabolism of S. cerevisiae.

Yeast cytochrome b2 gene: isolation with antibody probes

An efficient technique was used to clone the gene for yeast cytochrome b2, (a nuclear encoded mitochondrial protein) using the expression vector, lambda gt11 (lac 5 nin 5 c1857 S100). This enables the insertion of yeast DNA into the beta-galactosidase structural gene (lacZ) and promotes synthesis of hybrid proteins. Screening of antigen producing clones in the lambda gt11 recombinant genomic library was achieved using antiserum against cytochrome b2 according to Young and Davis (1983) Two recombinants containing part of the gene coding for cytochrome b2 were isolated and characterized as follows: by their expression in Escherichia coli cells, examined by immuno-blotting with antibodies to pure cytochrome b2. by DNA sequence analysis. One recombinant carries a 3 Kb yeast DNA insert which contains the whole nucleotide sequence encoding cytochrome b2 and a few amino acids of the amino terminal presequence.

Study of a zone highly sensitive to proteases in flavocytochrome b2 from Saccharomyces cerevisiae

Flavocytochrome b2 from baker's yeast is a bifunctional tetrameric protein which carries two prosthetic groups, FMN and heme, per subunit of Mr 58 000. The amino terminus of the subunit is wrapped around the heme and constitutes the so-called cytochrome b2 core (Mr 11 000), homologous to cytochrome b5. It has been shown in the past that a number of proteases (yeast proteases, chymotrypsin) preferentially cleave the peptide chain at a point situated much further down the polypeptide chain than the C terminus of the heme-binding domain. Some enzymatic parameters are concomitantly modified, but not the quaternary structure. This paper describes the conditions for selective proteolysis of intact flavocytochrome b2 and of its various previously studied stable nicked forms by the protease from Staphylococcus aureus V8. Successive attack by a combination of two proteases is also described. We have established the amino acid sequence of the area where proteolytic attack takes places, and shown that chymotrypsin and S. aureus protease open only one bond, whereas yeast proteases remove five residues from the central part. The various nicked forms, some of which have lost up to 16 amino acid residues, have been enzymatically characterized. These and previous results lend support to, but do not prove, the idea that the flavodehydrogenase part of flavocytochrome b2 may be composed of two domains, linked by the region accessible to proteases. That area might constitute a hinge or rather a clasp between the domains.

A flavin-mononucleotide-binding site in Hansenula anomala nicked flavocytochrome b2, requiring the association of two domains

Previous experiments in our laboratory with Saccharomyces cervisiae flavocytochrom b2 indicated that both fragments alpha and beta of the enzyme after cleavage by yeast proteases are required to form the flavin site. More detailed experiments have not been carried out on the nicked Hansenula anomala enzyme obtained by tryptic cleavage. A method has been devised that gives a quantitative separation in 4 M urea of beta, and alpha with its heme still bound. The characteristics of the various species: isolated alpha and beta and mixed alpha + beta were studied in 4 M urea and after elimination of this reagent by dialysis in the presence of FMN and 2-mercaptoethanol. Several methods, including heme spectroscopy, tryptophan fluorescence, sedimentation studies, and titration of bound flavin, were used. The results indicate that isolated alpha and beta have a folded globular structure after renaturation. The flavin binding to the alpha + beta mixture was important (50-100%) with recovery of the flavodehydrogenase activity. In contrast, binding was not detectable (< 0.5%, Kf > 10 mM) for isolated alpha and beta. As far as mononucleotide binding is concerned, such a cooperative requirement for two folding domains has never been reported in other enzymes. The present results are discussed together with others obtained in our laboratory which demonstrate that, as deduced from their sensitivity to trypsin, the structure of S. cerevisiae and H. anomala flavocytochrome b2 protomers is triglobular 'n-x-beta' (n and x combined within alpha). The tetramer assembly, which remains intact as a nicked enzyme (alpha beta)4 after the first trypsin cleavage, is broken down following a second cleavage of the chain into four cytochrome cores (n) and a functional T-flavodehydrogenase entity, a tetramer of the type (x beta)4.

Surface differences and similarities in two homologous proteins. Cytochrome b5 and cytochrome b2 core

From previous work (Guiard, B., Groudinsky, O. and Lederer, F. (1974) Proc. Natl. Acad. Sci. U.S. 71, 2539-2543) it is now clear that the overall secondary and tertiary structure of cytochrome b2 core is very similar to that of cytochrome b5. We present here a direct comparison of circular dichroism spectra and low-temperature absorption spectra which bring further evidence about this structural similarity. Cytochrome b2 core reacts only sluggishly with cytochrome b5 reductase, showing a lack of correspondence with the reductase binding area in cytochrome b5. On the other hand, literature data indicate similar electron transfer rates between cytochrome c on one hand, cytochrome b5 and cytochrome b2 core on the other hand. A structural inspection of cytochrome b2 core suggests that the mouth of the heme crevice in the latter is the most likely region for interaction with cytochrome c, with perhaps ionic bonds slightly different from those proposed by Salemme (Salemme, F.R. (1976) J. Mol. Biol. 102, 563--568) for the cytochrome c-cytochrome b5 interaction. In view of this partial surface similarity, the lack of immunological cross-reactivity between the two hemoprotein cores is attributed to their close similarity with the cytochrome b5 of the antibody-producing rabbit.

Sulfite binding to a flavodehydrogenase, cytochrome b2 from baker's yeast

Baker's yeast L-lactate dehydrogenase (flavocytochrome b2) is a typical flavodehydrogenase, in that it accepts two electrons from the substrate but has a monoelectronic acceptor. Yet it forms a red semiquinone [Capeillère Blandin et al. Eur. J. Biochem. 54, 549--566 (1975)] and it is shown in this paper that it forms a reversible covalent complex with sulfite (Kd = 1.4 muM). This complex can be observed by difference spectroscopy and provides a convenient tool for visualizing the flavin chromophore, usually hidden behind the intense heme absorbance. A number of anions (D-lactate, oxalate and pyruvate) are inhibitors of the enzymatic reaction and induce spectral perturbations of the flavin spectrum. It is concluded that probably two positive charges exist at the active site: one which stabilizes the red semiquinone and one which attracts organic anions and sulfite. It is also concluded that the correlation between reactivity with sulfite and reactivity with oxygen among flavo-proteins may not be as general as previously proposed [Massey et al. J. Biol. Chem. 244, 3999--4006 (1969)].

The "b5-like" domain from chicken-liver sulfite oxidase: a new case of common ancestral origin with liver cytochrome b5 and bakers' yeast cytochrome b2 core

Limited chymotryptic digestion of chicken-liver sulfite oxidase destroys its ability to oxidize sulfite. From the digest can be isolated a heme-binding fragment of molecular weight about 11 000. Its purification is described, as well as its characterization by a number of methods (absorption spectroscopy, circular dichroism, electrophoretic mobility, immunochemical reactivity, amino acid analysis). The heme spectrum shows no detectable difference with that of the native enzyme. The N-terminal sequence of this sulfite oxidase core is reported (34 residues). It shows a strong similarity to that of liver microsomal cytochrome b5 and bakers' yeast cytochrome b2 core. The sequence comparison is discussed in terms of structural similarity to cytochrome b5. Our data suggest a common evolutionary origin for the three b-type cytochromes.

Controlled proteolysis of flavocytochrome b2. Characterization of a 15000-dalton heme-binding core and comparison with detergent solubilized cytochrome b5

It is known that each subunit of the tetrameric flavocytochrome b2 can be cleaved by yeast proteases to fragments of molecular weight 33-36000 and 21 000, with some modification of catalytic properties, but without destruction of the oligomeric state of the protein. We report here experimental conditions which enabled us to simulate this specific cleavage in a controlled fashion with chymotrypsin and subtilisin. With trypsin and papain, on the other hand, it was not found possible to stop the digestion in such a way as to obtain a homogeneous still active product. A characterization of the enzymatic forms obtained by digestion with chymotrypsin and subtilisin at 0 degrees C shows that modification of enzymatic and solubility properties occurs in a stepwise fashion. It is also ccluded that cleavage by yeast proteases is accompanied by loss of 10 to 25 residues. At 37 degrees C, chymotrypsin digestion yields a heme-binding core of molecular weight 15 000, larger than the already characterized tryptic heme-binding core by about 40 residues. Although the latter is known to be very similar to trypsin-solubilized cytochrome b5, the lack of aggregation of the former in aqueous solution, its amino acid composition and circular dichroism spectra do not point to a similarity of its additional peptide segment with the hydrophobic tail of detergent-solubilized cytochrome b5.