Encapsulating genetically modified Saccharomyces cerevisiae cells in a flow-through device towards the detection of diclofenac in wastewater

Recently it has been proposed to use sensors based on genetically engineered reporter cells to perform continuous online water monitoring. Here we describe the design, assembly and performance of a novel flow-through device with immobilized genetically modified yeast cells that produce a fluorescent protein upon stimulation with diclofenac whose intensity is then detected by fluorescence microscopy. Although other devices employing immobilized cells for the detection of various analytes have already been described before, as novelty our system allows safe enclosure of the sensor cells, and thus, to obtain fluorescent signals that are not falsified by a loss of cells. Furthermore, the yeast cells are prevented from being released into the environment. Despite the safe containment, the immobilized reporter cells are accessible to nutrients and analytes. They thus have both the ability to grow and respond to the analyte. Both in cell culture medium and standardized synthetic wastewater, we are able to differentiate between diclofenac concentrations in a range from 10 to 100 μM. As particularly interesting feature, we show that only the biologically active fraction of diclofenac is detected. Nowadays, contamination of wastewater with diclofenac and other pharmaceutical residues is becoming a severe problem. Our investigations may pave the way for an easy-to-use and cost-efficient wastewater monitoring method.

Induction of apoptosis in human cancer cells by targeting mitochondria with gold nanoparticles

A major challenge in designing cancer therapies is the induction of cancer cell apoptosis, although activation of intrinsic apoptotic pathways by targeting gold nanoparticles to mitochondria is promising. We report an in vitro procedure targeting mitochondria with conjugated gold nanoparticles and investigating effects on apoptosis induction in the human breast cancer cell line Jimt-1. Gold nanoparticles were conjugated to a variant of turbo green fluorescent protein (mitoTGFP) harbouring an amino-terminal mitochondrial localization signal. Au nanoparticle conjugates were further complexed with cationic maltotriose-modified poly(propylene imine) third generation dendrimers. Fluorescence and transmission electron microscopy revealed that Au nanoparticle conjugates were directed to mitochondria upon transfection, causing partial rupture of the outer mitochondrial membrane, triggering cell death. The ability to target Au nanoparticles into mitochondria of breast cancer cells and induce apoptosis reveals an alternative application of Au nanoparticles in photothermal therapy of cancer.

Knockdown of human COX17 affects assembly and supramolecular organization of cytochrome c oxidase

Assembly of cytochrome c oxidase, the terminal enzyme of the mitochondrial respiratory chain, requires a concerted activity of a number of chaperones and factors for the insertion of subunits, accessory proteins, cofactors and prosthetic groups. It is now well accepted that the multienzyme complexes of the respiratory chain are organized in vivo as supramolecular functional structures, so-called supercomplexes. Here, we investigate the role of COX17 in the biogenesis of the respiratory chain in HeLa cells. In accordance with its predicted function as a copper chaperone and its role in formation of the binuclear copper centre of cytochrome c oxidase, COX17 siRNA knockdown affects activity and assembly of cytochrome c oxidase. While the abundance of cytochrome c oxidase dimers seems to be unaffected, blue native gel electrophoresis reveals the disappearance of COX-containing supercomplexes as an early response. We observe the accumulation of a novel approximately 150 kDa complex that contains Cox1, but not Cox2. This observation may indicate that the absence of Cox17 interferes with copper delivery to Cox2, but not to Cox1. We suggest that supercomplex formation is not simply due to assembly of completely assembled complexes. An interdependent assembly scenario for the formation of supercomplexes that rather requires the coordinated synthesis and association of individual complexes, is proposed.

Germ cell-less expression in medaka (Oryzias latipes)

The gene germ cell-less (gcl) plays an important role in the early differentiation of germ cells in Drosophila. We isolated the gcl homolog of the model teleost medaka (Oryzias latipes) using degenerated primers and an ovary cDNA bank. The predicted amino acid sequence of medaka gcl showed 92, 68 and 31% overall identity to mouse, human and Drosophila gcl respectively. RT-PCR revealed stronger expression in the ovary and weaker expression in testis, brain, heart, liver and muscle tissue. Expression in early embryos indicates the presence of maternal mRNA. By in situ hybridisation (ISH), gcl could not be detected in embryos. In contrast to vasa, ISH revealed expression of gcl in the ovary but not in the testis. Mol. Reprod. Dev. 67: 15-18, 2004.

Cytochrome c oxidase deficiency due to mutations in SCO2, encoding a mitochondrial copper-binding protein, is rescued by copper in human myoblasts

Mutations in SCO2, a cytochrome c oxidase (COX) assembly gene, have been reported in nine infants with early onset fatal cardioencephalomyopathy and a severe COX deficiency in striated muscle. Studies on a yeast homolog have suggested that human Sco2 acts as a copper chaperone, transporting copper to the Cu(A) site on the Cox II subunit, but the mechanism of action remains unclear. To investigate the molecular basis of pathogenesis of Sco2 defects in humans we performed genetic and biochemical studies on tissues, myoblasts and fibroblasts from affected patients, as well as on a recombinant human C-terminal Sco2 segment (22 kDa), bearing the putative CxxxC metal-binding motif. Recombinant Sco2 was shown to bind copper with a 1:1 stoichiometry and to form homomeric complexes in vitro, independent of the metal-binding motif. Immunohistochemistry using antibodies directed against different COX subunits showed a marked tissue-specific decrease in the Cox II/III subunits that form part of the catalytic core, consistent with the differential tissue involvement, but a more uniform distribution of Cox Vab, a nuclear-encoded subunit. Sco2 was severely reduced in patient fibroblasts and myoblasts by immunoblot analysis. Patient fibroblasts showed increased (64)Cu uptake but normal retention values and, consistent with this, the copper concentration was four times higher in Sco2-deficient myoblasts than in controls. COX activity in patient myoblasts was completely rescued by transduction with a retroviral vector expressing the human SCO2 coding sequence, and more interestingly by addition of copper-histidine (300 microM) to the culture medium. Whether the latter is accomplished by the very low residual levels of Sco2 in the patient cells, direct addition of copper to the Cu(A) site, or by another copper-binding protein remains unknown. Whatever the mechanism, this result suggests a possible therapy for the early treatment of this fatal infantile disease.

Expression of a VEGF-like protein from Parapoxvirus ovis in the yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe

We report on the expression of a VEGF-like protein encoded by Parapoxvirus ovis in the yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe. We show that a lysine residue at amino acid position 2 (K2) is an important determinant for the stability of this protein in S. cerevisiae. Replacement of K2 by an arginine results in stabilization of the protein. This observation suggests that this lysine may be a target for ubiquitinylation, which is a prerequisite for proteasome-mediated protein degradation. Interestingly, in S. pombe the lysine (K2) has no influence on the stability of the protein. This result indicates that the two yeast species exhibit significant differences in their protein degradation pathways.

The P(174)L mutation in the human hSCO1 gene affects the assembly of cytochrome c oxidase

Mutations of the yeast SCO1 gene result in impaired COX assembly. Recently, heterozygous mutations in the human homologue hSCO1 have been reported in infants suffering from neonatal ketoacidotic coma and isolated COX deficiency (Valnot et al., 2000). One of the hSCO1 alleles harboured a frame shift mutation resulting in a premature stop codon, the other a missense mutation leading to a substitution of proline(174) by leucine. This position is next to the essential CXXXC motif, which is conserved in all Sco1p homologues. We used chimeric proteins with the amino-terminal portion derived from yeast Sco1p and carboxy-terminal portion including the CXXXC motif from the human hSco1p to provide experimental evidence for the pathogenic nature of the P(174)L mutation. These chimeras are able to complement yeast sco1 null mutants. Introduction of the P(174)L mutation affects the function of these chimeric proteins severely, as shown by impaired COX assembly and loss of COX activity.

Yeast translational activator Cbs2p: mitochondrial targeting and effect of overexpression

The yeast translational activator protein Cbs2p is imported into mitochondria without obvious proteolytic processing. To test the importance of amino-terminal amino acids for mitochondrial targeting we fused varying portions of the N-terminus with green fluorescent protein and examined the intracellular distribution of the reporter protein. We show that the 25 N-terminal amino acids are sufficient to direct the majority of the fusion protein into mitochondria. Cbs2p derivatives lacking 9 to 35 amino acids from the N-terminus fail to complement the respiratory deficiency of a deltacbs2 strain, but are still imported into mitochondria. Therefore Cbs2p contains at least one independent mitochondrial targeting information in addition to the N-terminal signal. We further analyzed the effect of over-expression of Cbs2p on mitochondrial function. Elevated concentrations of Cbs2p lead to slightly impaired mitochondrial gene expression, probably as the result of the formation of inactive Cbs2p aggregates.

Mitochondrial copper metabolism in yeast: interaction between Sco1p and Cox2p

Yeast mitochondrial Sco1p is required for the formation of a functional cytochrome c oxidase (COX). It was suggested that Sco1p aids copper delivery to the catalytic center of COX. Here we show by affinity chromatography and coimmunoprecipitation that Sco1p interacts with subunit Cox2p. In addition we provide evidence that Sco1p can form homomeric complexes. Both homomer formation and binding of Cox2p are neither dependent on the presence of copper nor affected by mutations of His-239, Cys-148 or Cys-152. These amino acids, which are conserved among the members of the Sco1p family, have been suggested to act in the reduction of the cysteines in the copper binding center of Cox2p and are discussed as ligands for copper.

Identification of functionally important regions of the Saccharomyces cerevisiae mitochondrial translational activator Cbs1p

Translation of cytochrome b mRNA in yeast mitochondria requires activation by the nuclear-encoded Cbs1p. According to the current model, Cbs1p tethers cytochrome b mRNA to the inner mitochondrial membrane via interaction with the 5'-untranslated leader. Cbs1p is predicted to be a hydrophilic protein with two hydrophobic segments near the carboxyl-terminal end, which are both too short to span the membrane. Nevertheless Cbs1p is tightly associated with the mitochondrial membrane, as shown by its behaviour in extraction experiments with taurodeoxycholate. In an attempt to define functionally important regions of Cbs1p, we created a number of mutant alleles by random and directed mutagenesis. We report that a Cbs1p mutant protein lacking the mitochondrial presequence is still able to complement a Deltacbs1 strain, suggesting that the presequence does not contain essential mitochondrial targeting information. Mutations in a cluster of positively charged amino acids at the extremeC-terminus have no effect on Cbs1p function, but removal of this segment severely impairs Cbs1p function. Truncation of 12 or more amino acids from the C-terminus results in a completely defective protein. We further show that both short hydrophobic regions are essential for Cbs1p function, although membrane association is observed even in the absence of these regions.

Mutational analysis of yeast mitochondrial translational activator Cbs2p and of YHR063Cp, a protein with similarity to Cbs2p

Translation of mitochondrial cytochrome b in Saccharomyces cerevisiae requires the nuclearly encoded proteins Cbs1p, Cbs2p and Cbp6p. So far no homologs have been identified, except for the product of the S. cerevisiae orf YHR063C, which has some similarity to Cbs2p. Here we analyze the effect of a null mutation of YHR063C and show that it is not required for mitochondrial respiration. In addition, we report on the importance of the carboxyl-terminus of Cbs2p for its function. We show that truncations and some directed mutations in the carboxyl-terminal region of Cbs2p render the protein non-functional. The importance of the COOH-terminus is further underscored by the finding that mutational alteration of the cbs2-1 allele results in the substitution of Ile(372) by Lys.

Human members of the SCO1 gene family: complementation analysis in yeast and intracellular localization

Cytochrome c oxidase is a multiprotein complex in the mitochondrial membrane whose biogenesis requires a number of proteins besides the structural subunits. Several yeast proteins as well as a human disease-related protein have been reported which are involved in cytochrome c oxidase assembly. The S. cerevisiae Sco1p protein has been implicated in the transfer of copper to cytochrome c oxidase subunits Cox1p and/or Cox2p. Here we report on the complementation behavior in yeast of two recently identified ScSco1p homologs of chromosome 17 and chromosome 22 from human. When allotropically expressed in yeast, both genes fail to complement the lack of the ScSCO1 gene. However, a chimera of the N-terminal half of ScSco1p and the C-terminal half of the chromosome 17 homolog does substitute for the ScSco1p function. Interestingly, the respective chimera with the human homolog of chromosome 22 is not able to complement. Expression of EGFP fusions in HeLa cells shows that both human ScSco1p homologs are located in the mitochondria of human cells.

Mitochondrial copper metabolism in yeast: mutational analysis of Sco1p involved in the biogenesis of cytochrome c oxidase

Saccharomyces cerevisiae Sco1p is believed to be involved in the transfer of copper from the carrier Cox17p to the mitochondrial cytochrome c oxidase subunits 1 and 2. We here report on the results of a mutational analysis of Sco1p. The two cysteine residues of a potential metal-binding motif (CxxxC) are essential for protein function as shown by their substitution by alanines. Chimeras consisting of Sco1p and its homolog S. cerevisiae Sco2p restrict the specificity of Sco1p function to the N-terminal half of the protein. A candidate region for conferring specificity on Sco1p is a stretch of hydrophobic amino acids, which act as a membrane anchor. In line with this suggestion is the result that alterations of individual amino acids within this region impair Sco1p function.

Disseminated neocortical and subcortical encephalopathy (DNSE) with widespread activation of brain macrophages: a new dementia disorder? Autopsy reports of two postmenopausal women from families with mitochondrial DNA mutations

In this study we present 2 postmenopausal women who showed clinical symptoms that resembled those of a rather well-defined group of vascular dementia disorders, termed subcortical dementia (Binswanger disease, CADASIL). Patient 1 exhibited mitochondrial DNA (mtDNA) variants in the ND5 gene at position 13,708 and the Cytb gene at position 15,257. These DNA variants have been described in a number of neurologic disorders, but their pathogenetic potential is unclear. Patient 2 showed the same DNA alterations and an additional mtDNA variant at position 15,812 in the Cytb gene. The principal neurohistologic features of the 2 atrophic brains presented here include: subtotal selective neuronal cell loss in the cortex and, to a lesser degree, in the basal ganglia (claustrum, putamen, globus pallidus), sparing palaeocortex and periarchaeocortex, and a very characteristic and diagnostic feature was detachment of astrocytic processes from capillary walls resulting in pericapillary space formation. These pericapillary spaces were partially filled with macrophages. The spaces were not associated with total breakdown of the blood vessel walls as demonstrated by the absence of erythrocytes, lymphocytes, or polymorphonuclear leukocytes outside the vascular bed of the brain; progressive subcortical encephalopathy, as it is seen in subcortical dementia (Binswanger), but lacking arterial lipohyalinosis. The cerebral grey and white matter revealed cuffing of arteries and arterioles by adventitial macrophages. The neocortical and subcortical changes were accompanied by myriads of activated macrophages filled with lipids. The pathology of our 2 cases differs from that of other neurodegenerative disorders and we suggest the term of "disseminated neocortical and subcortical encephalopathy (DNSE) with widespread activation of brain macrophages".

A soluble 12-kDa protein of the mitochondrial intermembrane space, Mrs11p, is essential for mitochondrial biogenesis and viability of yeast cells

We have isolated an essential yeast gene termed MRS11, which codes for a soluble protein of the mitochondrial intermembrane space. Interestingly, this new gene shares many similarities with the previously characterized MRS5 gene: when expressed from a multicopy plasmid, MRS11 like MRS5 restores respiration competence to yeast strains defective in the splicing of mitochondrial group II introns. Both genes are essential for viability of yeast cells, as the disruption of either of them is lethal. The proteins encoded by MRS5 and MRS11, which display 35%, sequence identity are both located in the mitochondrial intermembrane space. Depletion of Mrs11p results in a phenotype similar to that observed in Mrs5p-depleted cells: accumulation of the precursor form of mitochondrial hsp60, inability to form spectrophotometrically detectable amounts of cytochromes and changes in the mitochondrial morphology. Although similar in sequence and function, Mrs5p and Mrs11p are not functionally equivalent and neither can substitute for the other, even when overexpressed. Taken together, our data suggest a cooperative mode of action of Mrs11p and Mrs5p in mitochondrial protein import or other related essential mitochondrial processes.

Translational activator proteins required for cytochrome b synthesis in Saccharomyces cerevisiae

In the yeast Saccharomyces cerevisiae translation of apocytochrome b, the only mitochondrially encoded subunit of ubiquinol-cytochrome c oxidoreductase, requires the products of at least three nuclear genes, CBP6, CBS1 and CBS2. In this article I review available data on CBS1p and CBS2p from the initial detection of the genes up to the current investigations on interacting components and the proteins' topology.

Mitochondrial tRNA(Gln) and tRNA(Thr) gene variants in Parkinson's disease

A number of neurodegenerative diseases including Parkinson's disease (PD) have been shown to be associated with polymorphic variants of mitochondrial DNA. The A4336G mutation in the tRNA(Gln) gene was reported to occur at a higher frequency in individuals with Parkinson's disease and Alzheimer's disease (AD) than in age-matched controls. Similarly, we recently noted an elevated frequency of alterations at positions 15927 and 15928 in the tRNA(Thr) gene, resulting in the loss of a HpaII site, in patients suffering from multiple sclerosis (MS) with severe optic involvement. Here we report on the result of screening 100 PD patients and 100 age- and sex-matched controls for the presence of the A4336G mutation and the loss of the HpaII site in the tRNA(Thr) gene. Our result shows that loss of the HpaII site is significantly more frequent in patients than in controls. In contrast, we were not able to detect a difference in the frequency of the A4336G mutation in the tRNA(Gln) gene between patients and controls.

Mitochondrial DNA mutations in multiple sclerosis patients with severe optic involvement

Preferential maternal transmission in familial cases and the occasional association of multiple sclerosis (MS) and LHON suggests an involvement of mtDNA mutations in the aetiology of MS.

MATERIAL & METHODS

DNA obtained from 100 MS patients with pathological alterations in visually evoked potentials and 100 controls, was used for PCR amplification of mtDNA segments. Mutations were identified by restriction enzyme analysis and DNA sequencing.

RESULTS

Whereas primary LHON mutations are not detected, MS patients show a higher percentage of secondary LHON mutations, usually in a combinatorial manner, than controls. Two neighbouring base pair substitutions that are alleles in a HpaII-polymorphism in the mt tRNA(Thr) gene are significantly more frequent in MS patients than in controls (p = 0.00018).

CONCLUSION

Primary LHON mutations are not characteristic for MS with optic involvement, but secondary LHON mutations and two substitutions abolishing a HpaII site in the mt tRNA(Thr) gene may contribute to the aetiology of MS with optic involvement.

Association of the LHON 13,708 and 15,257 mitochondrial DNA mutations with neurodegenerative diseases distinct from LHON

300 patients suffering from neurodegenerative diseases distinct from Leber hereditary optic neuropathy (LHON) were screened for the presence of mitochondrial DNA mutations. We report on nine patients, eight female and one male, who all harboured mutations at positions 13,708 and 15,257 of the mitochondrial DNA. Both mutations have previously been claimed to be associated with LHON. Based on our results, these mutations occur in a number of different neurodegenerative diseases and therefore cannot be regarded as "LHON" mutations.

[Mutations of the mitochondria genome. Diagnosis and pathogenetic significance]

The mitochondrial respiratory chain, which consists of five enzyme complexes, plays a central part in cellular energy metabolism. Thirteen of the protein sub-units are encoded by the mitochondrial genome, a circular DNA molecule of about 16,500 base pairs. Knowledge of the mitochondrial genome and alterations to it is essential to reveal functional defects of the respiratory chain. Point mutations, deletions and duplications of this DNA are associated with a growing number of diseases, whose clinical presentations vary quite widely.

Mitochondrial complex I and III mutations and neutral-lipid storage in activated mononuclear macrophages and neutrophils: a case presenting with necrotizing myopathy, poikiloderma atrophicans vasculare, and xanthogranulomatous bursitis

We report the case of a 57-year-old woman suffering from xanthogranulomatous bursitis, necrotizing myopathy, and poikiloderma atrophicans vasculare, which are associated with marked accumulation of neutral-lipid storage phagocytes. The observed lipid storage was restricted to activated phagocytes independent of the presence of tissue necrosis and was not seen either in circulating blood leukocytes or in muscle fibers. The patient's daughter disclosed xanthomatous inflammatory reaction with profound delay of wound healing secondary to pelviscopy. Examination of the mitochondrial DNAs of the patient, her daughter, and her two grandchildren revealed two homoplasmic mutations at positions 13708 and 15257 of the mitochondrial genome. We discuss the involvement of these mutations in the pathogenesis of xanthomatous and xanthogranulomatous inflammation. Further investigations are required to test whether impairment of aerobic energy production independent from mitochondrial DNA mutations (eg, by hypoxia or microbial toxins) similarly can cause the accumulation of lipid-laden macrophages and explain the persistency of xanthogranulomatous inflammation.

Expression of the Saccharomyces cerevisiae CYT2 gene, encoding cytochrome c1 heme lyase

In this paper we examine the expression of the Saccharomyces cerevisiae CYT2 gene, which encodes cytochrome c1 heme lyase. This enzyme is required for covalent attachment of heme to apocytochrome c1, a subunit of the mitochondrial respiratory chain. Transcription of the 1-kb CYT2 mRNA initiates at four prominent sites at a distance of 52-225 bp in front of the AUG start codon. The level of CYT2 mRNA is not influenced by the presence or absence of oxygen or of heme, but it is subject to carbon-source control. The concentration of the CYT2 mRNA is significantly reduced in glucose-grown cells as compared to cells grown under non-repressing conditions. Neither the HAPp activator proteins nor MIG1p, a repressor protein involved in glucose repression, seem to mediate this effect.

In situ autolysis of mouse brain: ultrastructure of mitochondria and the function of oxidative phosphorylation and mitochondrial DNA

The effect of in situ autolysis on cerebral mitochondrial structure and function has been investigated. Mice (n = 9) were sacrificed and stored for up to 24 h under unfavorable post-mortem conditions at 25 degrees C. At different time intervals groups of three animals were submitted to post-mortem dissection and tissue from different regions of the brain was used for the preparation of "free" and synaptosomal mitochondria. On electron microscopic examination, the post-mortem period had no significant influence on mitochondrial morphology and enzymatic activities of complexes I-V of the mitochondrial oxidative phosphorylation system were still present in all the mitochondrial preparations from different regions of the brain, albeit at a reduced levels. Degradation of mitochondrial DNA was virtually absent from mitochondrial preparations during the 24-h period of autolysis, as shown by the presence of intact DNA by Southern blot and PCR analysis. Based on these results, alterations in mitochondrial DNA and deficiencies of mitochondrial respiratory complexes I-V can be recognized in cerebral tissue even after 24 h of unfavorable post-mortem storage conditions.

Neutrophilic migration through capillarylike micropores: influence of pulmonary passage

We report the effect of pulmonary passage on random migration and chemokinesis of neutrophils through capillarylike pores under the in vitro condition of Boyden's test. Neutrophils were isolated either from the left ventricle or from the pulmonary artery of patients who underwent coronary angiography due to suspected angina pectoris or valvular heart disease. In all 14 cases left ventricle neutrophils showed significantly enhanced chemotactic-activated migration compared with pulmonary artery neutrophils. Pulmonary passage also influenced the random migration of neutrophils, except for those derived from five patients suffering from pulmonary hypertension. Our findings might indicate that accumulation of neutrophils in the capillaries of the normal lung is counteracted by a change in neutrophilic migration behavior during pulmonary passage, thus avoiding increased neutrophilic sequestration in pulmonary microcirculation as observed in adult respiratory distress syndrome.

A fluorescence-microscopic and flow-cytometric study of HeLa cells with an experimentally induced respiratory deficiency

HeLa cells, cultured over a long period in a medium containing low doses of ethidiumbromide, were used as a model system for flow-cytometric detection of human cells with impaired mitochondrial respiratory function. Based on laserscan and flowcytometric analysis after rhodamine 123 staining, the mitochondrial membrane potential of respiratory deficient cells seems unchanged as compared to control cells. Maintenance of this membrane potential in respiration-impaired cells requires glycolytic ATP generation, as transient inhibition of glycolysis by sodium fluoride affects rhodamine 123 accumulation in ethidiumbromide-treated cells, but not in control cells. We present a protocol which allows the detection and separation of respiratory deficient cells by flow cytometry.

Molecular cloning and characterization of the Saccharomyces cerevisiae CYT2 gene encoding cytochrome-c1-heme lyase

Cytochrome c1, a subunit of the mitochondrial ubiquinol--cytochrome-c reductase, is synthesized on cytosolic ribosomes as a precursor protein of 37 kDa. Maturation to the mature 31-kDa form involves two proteolytic processing steps of the amino-terminal presequence. After removal of the amino-terminal part by the matrix-localized processing peptidase, the carboxy-terminal part of the presequence is cleaved off by an unknown intermembrane space protease. This step depends on covalent linkage of heme to the apoprotein. At least two complementation groups (I and II) can be distinguished among mutants of the yeast Saccharomyces cerevisiae, which are defective in this second proteolytic processing, i.e. they accumulate the intermediate-sized form of cytochrome c1 instead of the mature form. Recently, it was shown that complementation group II defines the structural gene for cytochrome c1 [Sadler, I., Suda, K., Schatz, G., Kaudewitz, F. & Haid, A., (1984) EMBO J. 3, 2137-2143]. We report on the molecular cloning and characterization of the CYT2 gene representing complementation group I. It maps on chromosome XI and encodes a mitochondrial protein of about 26 kDa. Extensive similarity to Neurospora crassa and S. cerevisiae cytochrome-c--heme lyase, as well as the phenotype of cyt2 mutants, strongly suggest that we have identified the gene for cytochrome-c1--heme lyase.

AUG codons in the RNA leader sequences of the yeast PET genes CBS1 and SCO1 have no influence on translation efficiency

We report that the major transcription start sites of the yeast PET gene SCO1 are located at positions -149 and -125 relative to the AUG initiation codon of the SCO1 reading frame. The leader sequences of the resulting mRNAs possess a single AUG codon at position -49, which initiates a short open reading frame of three amino acids. The recent finding of a similar situation in the case of the PET gene CBS1 prompted us to address the question as to whether these AUG codons might play some role in the expression of these PET genes. After removal of the upstream AUG codons by site-directed mutagenesis, expression was monitored by use of lacZ fusions and compared to the respective wild-type constructs. Our data show that under all growth conditions tested the leader-contained AUG initiation codons have no significant influence on the expression of both PET genes.

Association of cytochrome b translational activator proteins with the mitochondrial membrane: implications for cytochrome b expression in yeast

The products of the nuclear genes CBS1 and CBS2 are both required for translational activation of mitochondrial apocytochrome b in yeast. We report the intramitochondrial localization of both proteins by use of specific antisera. Based on its solubilization properties the CBS1 protein is presumed to be a component of the mitochondrial membrane; the detergent concentrations needed to release CBS1 from mitochondria are almost the same as for cytochrome c1. In contrast, CBS2 behaves like a soluble protein, with some characteristics of a membrane-associated protein. A model is presented for translational activation of cytochrome b, which might also be applicable to translational regulation of other mitochondrial genes.

Immunological identification of yeast SCO1 protein as a component of the inner mitochondrial membrane

The SCO1 gene of Saccharomyces cerevisiae encodes a 30 kDa protein which is specifically required for a post-translational step in the accumulation of subunits 1 and 2 of cytochrome c oxidase (COXI and COX-II). Antibodies directed against a beta-Gal::SCO1 fusion protein detect SCO1 in the mitochondrial fraction of yeast cells. The SCO1 protein is an integral membrane protein as shown by its resistance to alkaline extraction and by its solubilization properties upon treatment with detergents. Based on the results obtained by isopycnic sucrose gradient centrifugation and by digitonin treatment of mitochondria, SCO1 is a component of the inner mitochondrial membrane. Membrane localization is mediated by a stretch of 17 hydrophobic amino acids in the amino-terminal region of the protein. A truncated SCO1 derivative lacking this segment, is no longer bound to the membrane and simultaneously loses its biological function. The observation that membrane localization of SCO1 is affected in mitochondria of a rho0 strain, hints at the possible involvement of mitochondrially coded components in ensuring proper membrane insertion.

Over-expression, purification and determination of the proteolytic processing site of the yeast mitochondrial CBS1 protein

Yeast transformants harboring the CBS1 gene under the control of the strong ADC1 promoter on a high copy number plasmid express the mitochondrial CBS1 protein at artificially high levels. Over-expressed protein is imported into mitochondria and correctly processed to yield the mature mitochondrial 23.5 kDa form, but differs in its solubility properties from CBS1 in wild-type mitochondria. It forms insoluble protein aggregates, which are refractory to solubilization with 1% Taurodeoxycholate. We exploited this observation to separate CBS1 from the bulk of mitochondrial proteins and to isolate CBS1 after SDS gel electrophoresis. Determination of the amino-terminal amino acids of the purified protein reveals that the mature CBS1 protein starts with Ile30, at the characteristic distance of +2 amino acids from an arginine residue (Arg28). The cleavage site shows a remarkable homology to that of subunit 9 of the F0F1 ATPase from Neurospora crassa.

Functional and molecular analysis of mitochondria in thyroid oncocytoma

We report a functional and molecular analysis of nine oncocytic tumors of the human thyroid. In all the abundance of mitochondria observed ultrastructurally was accompanied by an increase in enzymatic activities of respiratory complexes 1 (NADH dehydrogenase), 11 (succinate dehydrogenase) IV (cytochrome c oxidase), and V (ATPase). Western blot analysis failed to detect uncoupling protein in the tumors. The elevated respiratory enzyme activities were paralleled by an increase in the mitochondrial DNA content. Restriction analysis of mitochondrial DNA gave no indication of heteroplasmy or other gross alterations. We conclude that the mitochondrial proliferation in oncocytic tumors is probably not the result of a compensatory mechanism for the deficiency in enzyme complexes of the mitochondrial respiratory chain.

Flow cytometry as a tool to discriminate respiratory-competent and respiratory-deficient yeast cells

The cationic lipophilic dye Rhodamine 123 (Rh123) is selectively enriched in mitochondria in a membrane potential-dependent manner. Application of drugs which interfere with the electron flow of the respiratory chain lead to a severe reduction of mitochondrial dye uptake. In this communication we show that the same effect is observed after Rh123-staining of respiratory-deficient yeast mutants. Based on this observation we used flow cytometry to discriminate respiratory-competent and respiratory-deficient yeast cells. Combined with a cell sorter we were able to selectively enrich respiring and non-respiring yeast cells, respectively, from a mixture of cells.

Transcription of two divergently transcribed yeast genes initiates at a common oligo(dA-dT) tract

Oligo(dA-dT) tracts are frequently found in the intergenic regions of the yeast Saccharomyces cerevisiae and have been proposed to act as upstream promoter elements for constitutive transcription. An oligo(dA-dT) tract of 23 bp is also found as a characteristic sequence motif in the centre of the 230 bp segment which separates the open reading frames of the CBS2 gene and its 5'-flanking gene on chromosome IV. Recently we have reported that transcription of CBS2 is initiated immediately adjacent to this oligo(dA-dT) tract (michaelis et al. 1988). Here we report that the flanking gene of unknown function is divergently transcribed into an RNA with heterogeneous 5' ends. Two of these 5' ends map within the oligo(dA-dT) stretch, while the third is located upstream, leading to an RNA species which is partially complementary to the CBS2 transcript. Gel shift assays show that the oligo(dA-dT) stretch is specifically recognized by (a) binding factor(s) in nuclear extracts. We discuss these results with respect to the role of oligo(dA-dT) stretches in gene expression in yeast.

Identification of CBS2 as a mitochondrial protein in Saccharomyces cerevisiae

The nuclear genome encoded yeast protein CBS2 is required for translational activation of mitochondrial cytochrome b RNA. Genetic studies have shown that the target sequence of the CBS2 protein is the 5' untranslated leader sequence of cytochrome b RNA. Here we report on the intracellular localization of CBS2. CBS2 protein, expressed in Escherichia coli and prepared from inclusion bodies, was used as an antigen to raise a polyclonal rabbit antiserum. Affinity-purified CBS2 antibodies detect a 45 kDa protein in mitochondrial lysates of wild-type cells, which is absent in a strain in which the CBS2 gene has been deleted. The protein is overexpressed in mitochondrial extracts of a transformant carrying the CBS2 gene on a high copy number plasmid, but undetectable in the post-mitochondrial supernatant. Intramitochondrial localization of CBS2 was verified by in vitro import of CBS2 protein that had been synthesized in a reticulocyte lysate programmed with CBS2 mRNA transcribed in vitro. Mitochondrial import of CBS2 is not accompanied by any detectable proteolytic processing.

Yeast SCO1 protein is required for a post-translational step in the accumulation of mitochondrial cytochrome c oxidase subunits I and II

Biogenesis of functional cytochrome c oxidase in yeast requires the product of the nuclear gene SCO1. Strains deleted for this gene fail to accumulate the mitochondrially-synthesized cytochrome c oxidase subunits I and II, despite the presence of the respective mRNAs. Here we present data which demonstrate that the observed phenotype does not result from a failure to translate the mRNAs, but from a preferential degradation of the newly synthesized subunits. The SCO1 protein is therefore involved in a post-translational step in the accumulation of cytochrome c oxidase subunits I and II. We propose that the SCO1 protein is required for the correct assembly of both subunits into the cytochrome c oxidase complex.

Chromosomal localization and expression of CBS1, a translational activator of cytochrome b in yeast

Translation of mitochondrial cytochrome b RNA in yeast requires the product of the nuclear gene CBS1, a 27.5 kDa soluble mitochondrial protein. In this paper we show that the CBS1 gene is located on chromosome IV immediately adjacent to COX9, the gene coding for cytochrome c oxidase subunit VIIa. CBS1 is transcribed as a very low abundant 900 b RNA. Transcription starts at a single position 101 bp upstream of the CBS1 initiation codon. At positions -39 to -27 of its leader sequence it contains a small open reading frame of 4 codons. By monitoring the beta-galactosidase activity of a CBS1/lacZ fusion construct we show that expression of CBS1 is subjected to regulation by oxygen and by glucose: the beta-galactosidase activity is elevated threefold in glycerol or galactose grown cells compared to that in glucose grown cells. A further threefold reduction of the activity is observed in anaerobically grown cells. In accordance with this result is the observation that the steady-state level of CBS1 mRNA of anaerobically grown cells is ninefold lower than that of aerobically cultured cells.

In vitro and in vivo studies on the mitochondrial import of CBS1, a translational activator of cytochrome b in yeast

Translation of mitochondrial cytochrome b mRNA in yeast is activated by the product of the nuclear gene CBS1. CBS1 encodes a 27 kDa precursor protein, which is cleaved to a 24 kDa mature protein during the import into isolated mitochondria. The sequences required for mitochondrial import reside in the amino-terminal end of the CBS1 precursor. Deletion of the 76 amino-terminal amino acids renders the protein incompetent for mitochondrial import in vitro and non-functional in vivo. When present on a high copy number plasmid and under the control of a strong yeast promoter, biological function can be restored by this truncated derivative. This observation indicates that the CBS1 protein devoid of mitochondrial targeting sequences can enter mitochondria in vivo, possibly due to a bypass of the mitochondrial import system.

Accumulation of the cytochrome c oxidase subunits I and II in yeast requires a mitochondrial membrane-associated protein, encoded by the nuclear SCO1 gene

The yeast nuclear SCO1 gene is required for accumulation of the mitochondrially synthesized cytochrome c oxidase subunits I and II (COXI and COXII). We cloned and characterized the SCO1 gene. It codes for a 0.9 kb transcript. DNA sequence analysis predicts a 33 kDa protein. As shown by in vitro transcription and translation experiments in combination with import studies on isolated mitochondria, this protein is matured into a 30 kDa polypeptide which is tightly associated with a mitochondrial membrane. The possible function of the SCO1 gene product in the assembly of cytochrome c oxidase is discussed.

Yeast nuclear gene CBS2, required for translational activation of cytochrome b, encodes a basic protein of 45 kDa

In yeast, synthesis of apocytochrome b from mitochondrial COB mRNA depends on at least three nuclear gene products. The translation stimulatory effect by two of these nuclear genes, CBS1 and CBS2, is mediated by the 5'-untranslated leader of COB mRNA. In this report, we show that CBS2 is located on chromosome IV and provide genetic evidence that the CBS2 gene encodes a polypeptide. Determination of the DNA sequence reveals a contiguous open reading frame of 1167 bp. The deduced polypeptide has a calculated molecular weight of 44.5 kDa and is characterized by a high content of positively charged amino acids. It has no significant homology to any known protein. The CBS2 gene is transcribed into low abundance mRNA species with a major transcription initiation site located 97 bp upstream from the ATG start codon next to a poly(dA-dT) stretch.

SCO1, a yeast nuclear gene essential for accumulation of mitochondrial cytochrome c oxidase subunit II

We have identified and isolated a novel yeast nuclear gene (SCO1) which is essential for accumulation of the mitochondrially synthesized subunit II of cytochrome c oxidase (CoxII). Analysis of the mitochondrial translation products in a sco1-1 mutant reveals a strong reduction in CoxII. Examination of mitochondrial transcripts by Northern blot hybridization shows that transcription and transcript maturation of OXI1, the gene coding for CoxII, is not affected. Therefore the SCO1 gene product must be involved in a post-transcriptional step in the synthesis of CoxII. We have isolated a 1.7 kb DNA fragment from a yeast gene bank which carries the functional SCO1 gene. Two RNA species of 0.9 kb and 1.2 kb, respectively, hybridize with this DNA fragment, which is localized on chromosome II. Cells whose chromosomal 1.7 kb fragment has been replaced by the yeast URA3 gene fail to accumulate CoxII and in addition subunit I of cytochrome c oxidase (CoxI). The possibility that the SCO1 gene product is bifunctional, i.e. required for both CoxI and CoxII accumulation, is discussed.

The yeast nuclear gene CBS1 is required for translation of mitochondrial mRNAs bearing the cob 5' untranslated leader

Mitochondrial translation of the cob mRNA to yield apocytochrome b is specifically dependent on the nuclear gene CBS1, while mitochondrial translation of the oxi2 mRNA to yield cytochrome oxidase subunit III (cox III) is specifically dependent on the nuclear gene PET494. Chimeric oxi2 mRNAs bearing the 5' leaders of other mitochondrial mRNAs, transcribed from rho- mitochondrial DNAs termed MSU494, are translated in pet494 mutants. In this study, we examined translation of coxIII from MSU494-encoded chimeric mRNAs in zygotes of defined nuclear and mitochondrial genotype. CoxIII was translated from a chimeric mRNA bearing the cob leader only when the zygotes contained a wild-type CBS1 gene. CoxIII translation from an mRNA bearing the 5' leader of the mitochondrial gene aap1 was not dependent on CBS1 activity. We conclude that the product of the nuclear gene CBS1, or something under its control, acts in the mitochondrion on the cob mRNA 5' leader to activate translation of down-stream coding sequences.

Cloning of a nuclear gene MRS1 involved in the excision of a single group I intron (bI3) from the mitochondrial COB transcript in S. cerevisiae

The respiratory deficient yeast nuclear mutant MK3 is defective in the synthesis of the mature transcripts of the mitochondrial COB and OX13 genes, which code for apocytochrome b and subunit I of cytochrome c oxidase, resp. Introns 3 and 4 of the COB transcript (bI3 and bI4) and intron 4 (aI4) of the OXI3 transcript can not be excised (Pillar et al. 1983a, b). When combined with mitochondrial genomes lacking introns bI1, bI2 and bI3, or lacking intron bI3 alone the mutant is respiratory competent. Thus, the non-excision of bI4 and aI4 turns out to be an indirect effect of the mutation. From a wild type yeast genebank a plasmid has been isolated with a 3.3 kb DNA insert, which complements the mutant. Subcloning experiments assigned the functional gene to a 1.6 kb HaeIII-Sau3A fragment. Hybridization experiments showed, that it is (i) a single copy gene, (ii) also present in strain D273-10B, containing the "short form" mitochondrial genome (lacking the COB introns bI1-bI3), and (iii) located on chromosome IX. The nuclear gene defective in mutant MK3, was named MRS1 (Mitochondrial RNA Splicing). The involvement of this nuclear gene in the excision of a single group I mitochondrial intron (bI3) of the COB transcript is discussed.

Molecular cloning of the yeast nuclear genes CBS1 and CBS2

The yeast nuclear genes CBS1 and CBS2 are both required for translation of the mitochondrial COB transcripts. Here we report on the identification of two unique chromosomal DNA-sequences of 2 kb and 2.3 kb from yeast wild type gene banks which functionally complement cbs1 and cbs2 mutants, respectively. Disruption of the homologous DNA-fragments by insertion of the URA3 gene generates respiratory deficient cells which fail to complement the original mutants. Cells with these gene disruptions are phenotypically identical to the original cbs1 and cbs2 mutants with respect to cytochrome spectra and mitochondrial translation products. The results exclude the possibility that suppressor genes have been cloned and confirm the conclusion that both genes, CBS1 and CBS2, specifically are involved in translation of mitochondrial COB RNA.

Two yeast nuclear genes, CBS1 and CBS2, are required for translation of mitochondrial transcripts bearing the 5'-untranslated COB leader

Mutations in one of the yeast nuclear genes CBS1 or CBS2 both prevent the excision of the maturase-coding introns bI2, bI3 and bI4 from the mitochondrial COB precursor transcript. Mutant strain MK2 (cbs1-1) has recently been reported to be primarily defective in the translation of COB transcripts, as it can be suppressed by a fusion of the COB structural gene with the 5' untranslated leader of the mitochondrial OLI1 gene (G. Rödel, A. Körte and F. Kaudewitz, Curr Genet 9: 641-648). Here I report that the effect of mutation cbs2-1, too, is suppressed by this gene rearrangement. CBS2 is the second nuclear gene identified which is involved in the translation of mitochondrial transcripts bearing the 5' untranslated COB leader. Gene specific translation control appears to be a major mode of regulation of mitochondrial gene expression in Saccharomyces cerevisiae.