Translational activators and mitoribosomal isoforms cooperate to mediate mRNA-specific translation in Schizosaccharomyces pombe mitochondria.

Mitochondrial mRNAs encode key subunits of the oxidative phosphorylation complexes that produce energy for the cell. In Saccharomyces cerevisiae, mitochondrial translation is under the control of translational activators, specific to each mRNA. In Schizosaccharomyces pombe, which more closely resembles the human system by its mitochondrial DNA structure and physiology, most translational activators appear to be either lacking, or recruited for post-translational functions.

Artemisinin and its derivatives target mitochondrial c-type cytochromes in yeast and human cells.

Artemisinin and its derivatives kill malaria parasites and inhibit the proliferation of cancer cells. In both processes, heme was shown to play a key role in artemisinin bioactivation. We found that artemisinin and clinical artemisinin derivatives are able to compensate for a mutation in the yeast Bcs1 protein, a key chaperon involved in biogenesis of the mitochondrial respiratory complex III.

Complete Sequence of the Intronless Mitochondrial Genome of the Saccharomyces cerevisiae Strain CW252.

The mitochondrial genomes of strains contain up to 13 introns. An intronless recombinant genome introduced into the nuclear background of strain W303 gave the CW252 strain, which is used to model mitochondrial respiratory pathologies. The complete sequence of this mitochondrial genome was obtained using a hybrid assembling methodology.

Development of an in silico method for the identification of subcomplexes involved in the biogenesis of multiprotein complexes in Saccharomyces cerevisiae.

Background: Large sets of protein-protein interaction data coming either from biological experiments or predictive methods are available and can be combined to construct networks from which information about various cell processes can be extracted. We have developed an in silico approach based on these information to model the biogenesis of multiprotein complexes in the yeast Saccharomyces cerevisiae.

Results: Firstly, we have built three protein interaction networks by collecting the protein-protein interactions, which involved the subunits of three complexes, from different databases.

Ribosome recycling defects modify the balance between the synthesis and assembly of specific subunits of the oxidative phosphorylation complexes in yeast mitochondria.

Mitochondria have their own translation machinery that produces key subunits of the OXPHOS complexes. This machinery relies on the coordinated action of nuclear-encoded factors of bacterial origin that are well conserved between humans and yeast. In humans, mutations in these factors can cause diseases; in yeast, mutations abolishing mitochondrial translation destabilize the mitochondrial DNA.

Yeast as a system for modeling mitochondrial disease mechanisms and discovering therapies.

Mitochondrial diseases are severe and largely untreatable. Owing to the many essential processes carried out by mitochondria and the complex cellular systems that support these processes, these diseases are diverse, pleiotropic, and challenging to study. Much of our current understanding of mitochondrial function and dysfunction comes from studies in the baker's yeast Saccharomyces cerevisiae.

A novel mechanism involved in the coupling of mitochondrial biogenesis to oxidative phosphorylation.

Mitochondria are essential organelles that are central to a multitude of cellular processes, including oxidative phosphorylation (OXPHOS), which produces most of the ATP in animal cells. Thus it is important to understand not only the mechanisms and biogenesis of this energy production machinery but also how it is regulated in both physiological and pathological contexts. A recent study by Ostojić [Cell Metabolism (2013) 18, 567-577] has uncovered a regulatory loop by which the biogenesis of a major enzyme of the OXPHOS pathway, the respiratory complex III, is coupled to the energy producing activity of the mitochondria.

Does the study of genetic interactions help predict the function of mitochondrial proteins in Saccharomyces cerevisiae?

Mitochondria are complex organelles of eukaryotic cells that contain their own genome, encoding key subunits of the respiratory complexes. The successive steps of mitochondrial gene expression are intimately linked, and are under the control of a large number of nuclear genes encoding factors that are imported into mitochondria. Investigating the relationships between these genes and their interaction networks, and whether they reveal direct or indirect partners, can shed light on their role in mitochondrial biogenesis, as well as identify new actors in this process.

The energetic state of mitochondria modulates complex III biogenesis through the ATP-dependent activity of Bcs1.

Our understanding of the mechanisms involved in mitochondrial biogenesis has continuously expanded during the last decades, yet little is known about how they are modulated to optimize the functioning of mitochondria. Here, we show that mutations in the ATP binding domain of Bcs1, a chaperone involved in the assembly of complex III, can be rescued by mutations that decrease the ATP hydrolytic activity of the ATP synthase. Our results reveal a Bcs1-mediated control loop in which the biogenesis of complex III is modulated by the energy-transducing activity of mitochondria.

An in silico approach combined with in vivo experiments enables the identification of a new protein whose overexpression can compensate for specific respiratory defects in Saccharomyces cerevisiae.

Background: The mitochondrial inner membrane contains five large complexes that are essential for oxidative phosphorylation. Although the structure and the catalytic mechanisms of the respiratory complexes have been progressively established, their biogenesis is far from being fully understood. Very few complex III assembly factors have been identified so far.

Deleterious effect of the Qo inhibitor compound resistance-conferring mutation G143A in the intron-containing cytochrome b gene and mechanisms for bypassing it.

The mutation G143A in the inhibitor binding site of cytochrome b confers a high level of resistance to fungicides targeting the bc(1) complex. The mutation, reported in many plant-pathogenic fungi, has not evolved in fungi that harbor an intron immediately after the codon for G143 in the cytochrome b gene, intron bi2. Using Saccharomyces cerevisiae as a model organism, we show here that a codon change from GGT to GCT, which replaces glycine 143 with alanine, hinders the splicing of bi2 by altering the exon/intron structure needed for efficient intron excision.

A transcriptome screen in yeast identifies a novel assembly factor for the mitochondrial complex III.

Starting from a transcriptome based study of the spatio-temporal expression of yeast genes encoding mitochondrial proteins of unknown function, we have identified the gene BCA1 (YLR077W). A FISH analysis showed that the BCA1 mRNA co-localized with the mitochondrial network. Cellular fractionation revealed that Bca1 is bound to the mitochondrial inner-membrane and protrudes into the inter-membrane space.

A mutational analysis reveals new functional interactions between domains of the Oxa1 protein in Saccharomyces cerevisiae.

The Oxa1/YidC/Alb3 family plays a key role in the biogenesis of the respiratory and photosynthetic complexes in bacteria and organelles. In Saccharomyces cerevisiae, Oxa1 mediates the co-translational insertion of mitochondrially encoded subunits of the three respiratory complexes III, IV and V within the inner membrane and also controls a late step in complex V assembly. No crystal structure of YidC or Oxa1 is available and little is known about the respective role of each transmembrane segment (TM) and hydrophilic loop of this polytopic protein on the biogenesis of the three complexes.

Spatio-temporal dynamics of yeast mitochondrial biogenesis: transcriptional and post-transcriptional mRNA oscillatory modules.

Examples of metabolic rhythms have recently emerged from studies of budding yeast. High density microarray analyses have produced a remarkably detailed picture of cycling gene expression that could be clustered according to metabolic functions. We developed a model-based approach for the decomposition of expression to analyze these data and to identify functional modules which, expressed sequentially and periodically, contribute to the complex and intricate mitochondrial architecture.

Functional analysis of yeast bcs1 mutants highlights the role of Bcs1p-specific amino acids in the AAA domain.

The mitochondrial protein Bcs1p is conserved from Saccharomyces cerevisiae to humans and its C-terminal region exhibits an AAA (ATPases associated with diverse cellular activities) domain. The absence of the yeast Bcs1p leads to an assembly defect of the iron-sulfur protein (ISP) subunit within the mitochondrial respiratory complex III, whereas human point mutations located all along the protein cause various pathologies. We have performed a structure-function analysis of the yeast Bcs1p by randomly generating a collection of respiratory-deficient point mutants.

Multiple defects in the respiratory chain lead to the repression of genes encoding components of the respiratory chain and TCA cycle enzymes.

Respiratory complexes III, IV and V are formed by components of both nuclear and mitochondrial origin and are embedded in the inner mitochondrial membrane. Their assembly requires the auxiliary factor Oxa1, and the absence of this protein has severe consequences on these three major respiratory chain enzymes. We have studied, in the yeast Saccharomyces cerevisiae, the effect of the loss of Oxa1 function and of other respiratory defects on the expression of nuclear genes encoding components of the respiratory complexes and tricarboxylic acid cycle enzymes.

Respiratory mutations lead to different pleiotropic effects on OXPHOS complexes in yeast and in human cells.

Pleiotropic effects in the oxidative phosphorylation pathway (OXPHOS) were investigated in yeast respiratory mutants and in cells from patients with OXPHOS genetic alterations. The main differences between yeast and human cells were (1) the site of the primary defect that was associated with pleiotropic effects, yeast complex V and human complex IV, and (2) the nature of the complex targeted by the secondary effect, yeast complex IV and human complex I. The pleiotropic effects did not correlate with the organization of OXPHOS into supercomplexes and their functional consequences appeared to be a slowing down of the respiratory chain in order to avoid either an increase in the membrane potential or the accumulation of reduced intermediary components of the respiratory chain.

Roles of Oxa1-related inner-membrane translocases in assembly of respiratory chain complexes.

Members of the family of the polytopic inner membrane proteins are related to Saccharomyces cerevisiae Oxa1 function in the assembly of energy transducing complexes of mitochondria and chloroplasts. Here we focus on the two mitochondrial members of this family, Oxa1 and Cox18, reviewing studies on their biogenesis as well as their functions, reflected in the phenotypic consequences of their absence in various organisms. In yeast, cytochrome c oxidase subunit II (Cox2) is a key substrate of these proteins.

Preparation of respiratory chain complexes from Saccharomyces cerevisiae wild-type and mutant mitochondria : activity measurement and subunit composition analysis.

The mitochondrial oxidative phosphorylation involves five multimeric complexes imbedded in the inner membrane: complex I (Nicotinamide Adenine Dinucleotide (NADH) quinone oxidoreductase), II (succinate dehydrogenase), III (ubiquinol cytochrome c oxido reductase or bc1 complex), IV (cytochrome c oxidase), and V (ATP synthase). These respiratory complexes are conserved from the yeast Saccharomyces cerevisiae to human with the exception of complex I, which is replaced by three NADH dehydrogenases in S. cerevisiae.

UCP2 is a mitochondrial transporter with an unusual very short half-life.

This study focused on the stability of UCP2 (uncoupling protein 2), a mitochondrial carrier located in the inner membrane of mitochondrion. UCP2 is very unstable, with a half-life close to 30min, compared to 30h for its homologue UCP1, a difference that may highlight different physiological functions. Heat production by UCP1 in brown adipocytes is generally a long and adaptive phenomenon, whereas control of mitochondrial ROS by UCP2 needs more subtle regulation.

Rmd9p controls the processing/stability of mitochondrial mRNAs and its overexpression compensates for a partial deficiency of oxa1p in Saccharomyces cerevisiae.

Oxa1p is a key component of the general membrane insertion machinery of eukaryotic respiratory complex subunits encoded by the mitochondrial genome. In this study, we have generated a respiratory-deficient mutant, oxa1-E65G-F229S, that contains two substitutions in the predicted intermembrane space domain of Oxa1p. The respiratory deficiency due to this mutation is compensated for by overexpressing RMD9.

The transcriptional activator HAP4 is a high copy suppressor of an oxa1 yeast mutation.

Oxa1p is a key component of the machinery for the insertion of membrane proteins in mitochondria, and in the yeast Saccharomyces cerevisiae, the deletion of OXA1 impairs the biogenesis of the three respiratory complexes of dual genetic origin. Oxa1p is formed from three domains located in the intermembrane space, the inner membrane and the mitochondrial matrix. We have isolated a high copy suppressor able to partially compensate for the respiratory deficiency caused by a large deletion of the matrix domain.

Interaction between the oxa1 and rmp1 genes modulates respiratory complex assembly and life span in Podospora anserina.

A causal link between deficiency of the cytochrome respiratory pathway and life span was previously shown in the filamentous fungus Podospora anserina. To gain more insight into the relationship between mitochondrial function and life span, we have constructed a strain carrying a thermosensitive mutation of the gene oxa1. OXA1 is a membrane protein conserved from bacteria to human.

A yeast mitochondrial membrane methyltransferase-like protein can compensate for oxa1 mutations.

Members of the Oxa1p/Alb3/YidC family mediate the insertion of various organelle or bacterial hydrophobic proteins into membranes. They present at least five transmembrane segments (TM) linked by hydrophilic domains located on both sides of the membrane. To examine how Oxa1p structure relates to its function, we have introduced point mutations and large deletions into various domains of the yeast mitochondrial protein.

Redundancy in the function of mitochondrial phosphate transport in Saccharomyces cerevisiae and Arabidopsis thaliana.

Most cellular ATP is produced within the mitochondria from ADP and Pi which are delivered across the inner-membrane by specific nuclearly encoded polytopic carriers. In Saccharomyces cerevisiae, some of these carriers and in particular the ADP/ATP carrier, are represented by several related isoforms that are distinct in their pattern of expression. Until now, only one mitochondrial Pi carrier (mPic) form, encoded by the MIR1 gene in S.