A genome wide study in fission yeast reveals nine PPR proteins that regulate mitochondrial gene expression

Pentatricopeptide repeat (PPR) proteins are particularly numerous in plant mitochondria and chloroplasts, where they are involved in different steps of RNA metabolism, probably due to the repeated 35 amino acid PPR motifs that are thought to mediate interactions with RNA. In non-photosynthetic eukaryotes only a handful of PPR proteins exist, for example the human LRPPRC, which is involved in a mitochondrial disease. We have conducted a systematic study of the PPR proteins in the fission yeast Schizosaccharomyces pombe and identified, in addition to the mitochondrial RNA polymerase, eight proteins all of which localized to the mitochondria, and showed some association with the membrane. The absence of all but one of these PPR proteins leads to a respiratory deficiency and modified patterns of steady state mt-mRNAs or newly synthesized mitochondrial proteins. Some cause a general defect, whereas others affect specific mitochondrial RNAs, either coding or non-coding: cox1, cox2, cox3, 15S rRNA, atp9 or atp6, sometimes leading to secondary defects. Interestingly, the two possible homologs of LRPPRC, ppr4 and ppr5, play opposite roles in the expression of the cox1 mt-mRNA, ppr4 being the first mRNA-specific translational activator identified in S. pombe, whereas ppr5 appears to be a general negative regulator of mitochondrial translation.     

Deletion of the mitochondrial carrier genes MRS3 and MRS4 suppresses mitochondrial iron accumulation in a yeast frataxin-deficient strain

The mitochondrial solute carriers Mrs3p and Mrs4p were originally isolated as multicopy suppressors of intron splicing defects. We show here that MRS4 is co-regulated with the iron regulon genes, and up-regulated in a strain deficient for Yfh1p, the yeast homologue of human frataxin. Using in vivo 55Fe cell radiolabeling we show that in glucose-grown cells mitochondrial iron accumulation is 5-15 times higher in deltaYFH1 than in wild-type strain. However, although in a deltaYFH1deltaMRS3deltaMRS4 strain, the intracellular 55Fe content is extremely high, the mitochondrial iron concentration is decreased to almost wild-type levels. Moreover, deltaYFH1deltaMRS3deltaMRS4 cells grown in high iron media do not lose their mitochondrial genome. Conversely, a deltaYFH1 strain overexpressing MRS4 has an increased mitochondrial iron content and no mitochondrial genome. Therefore, MRS4 is required for mitochondrial iron accumulation in deltaYFH1 cells. Expression of the iron regulon and intracellular 55Fe content are higher in a deltaMRS3deltaMRS4 strain than in the wild type. Nevertheless, the mitochondrial 55Fe content, a balance between iron uptake and exit, is decreased by a factor of two. Moreover, 55Fe incorporation into heme by ferrochelatase is increased in an MRS4-overexpressing strain. The function of MRS4 in iron import into mitochondria is discussed.     

Metabolism of sphingosine 1-phosphate and lysophosphatidic acid: a genome wide analysis of gene expression in Drosophila

Lipids, in addition to being structural components of cell membranes, can act as signaling molecules. Bioactive lipids, such as sphingosine 1-phosphate (S1P) and lysophosphatidic acid (LPA), may act intracellularly as second messengers or be secreted and act as intercellular signaling molecules. Such molecules can affect a variety of cellular processes including apoptosis, proliferation, differentiation and motility. To investigate possible sources of bioactive lipids during development we have searched the Drosophila genome for homologs of genes involved in mammalian S1P and LPA metabolism. Here we report the developmental expression of 31 such genes by in situ hybridization to Drosophila embryos. Most show expression in specific tissues, with expression in the gut and nervous system being recurring patterns.     

Metabolism of sphingosine 1-phosphate and lysophosphatidic acid: a genome wide analysis of gene expression in Drosophila

Lipids, in addition to being structural components of cell membranes, can act as signaling molecules. Bioactive lipids, such as sphingosine 1-phosphate (S1P) and lysophosphatidic acid (LPA), may act intracellularly as second messengers or be secreted and act as intercellular signaling molecules. Such molecules can affect a variety of cellular processes including apoptosis, proliferation, differentiation and motility. To investigate possible sources of bioactive lipids during development we have searched the Drosophila genome for homologs of genes involved in mammalian S1P and LPA metabolism. Here we report the developmental expression of 31 such genes by in situ hybridization to Drosophila embryos. Most show expression in specific tissues, with expression in the gut and nervous system being recurring patterns.     

A multiple ATG gene knockout strain for yeast two-hybrid analysis

Autophagy is a major intracellular degradative pathway that is involved in many human diseases. The molecular mechanism of autophagy has been elucidated largely through studies on autophagy-related (Atg) proteins. One difficulty in understanding the mechanism of autophagy has been the lack of functional motifs in most of the Atg proteins. In the absence of this information, studies that have focused on the interactions between Atg proteins have shed light on their functions. However, in most studies, it is difficult to determine whether an interaction is direct or occurs through other Atg proteins, particularly in vivo. Here, we took advantage of a new reagent, a multiple knockout (MKO) strain lacking 24 ATG genes, and converted the strain into a yeast two-hybrid (Y2H) host strain. We introduced three reporter genes into the existing MKO strain, and analyzed known interactions in the new MKO Y2H strain background to verify its utility. We also probed a new interaction using the MKO Y2H strain, and our results suggest that Atg29 and Atg31 interact independently of other known Atg proteins, and this interaction may mediate the interaction between Atg17 and Atg29.     

A genome wide association analysis in the GENDER study

Percutaneous coronary intervention (PCI) has become an effective therapy to treat coronary artery diseases. However, one of the major drawbacks of PCI is the occurrence of restenosis in 8 to 40% of all treated patients. The GENetic Determinants of Restenosis (GENDER) project was designed to study the association between genetic polymorphisims and clinical restenosis. The discovery of genetic variants associated to the occurrence of restenosis after PCI may provide a more tailored therapy and may serve as rationale for new antirestenotic therapies. So far, several candidate gene approaches had already been performed in the GENDER samples but a Genome Wide Association Scan (GWAS) was still lacking. Here, we present preliminary results from the GWAS we are currently carrying out in the GENDER population. (Neth Heart J 2009;17:262–4.)     

Low iron concentration and aconitase deficiency in a yeast frataxin homologue deficient strain.

Deletion of the yeast frataxin homologue, YFH1, elicits accumulation of iron in mitochondria and mitochondrial defects. We report here that in the presence of an iron chelator in the culture medium, the concentration of iron in mitochondria is the same in wild-type and YFH1 deletant strains. Under these conditions, the activity of the respiratory complexes is restored. However, the activity of the mitochondrial aconitase, a 4Fe-4S cluster-containing protein, remains low. The frataxin family bears homology to a bacterial protein family which confers resistance to tellurium, a metal closely related to sulfur. Yfh1p might control the synthesis of iron-sulfur clusters in mitochondria.     

Cell dynamics and gene expression control in tissue homeostasis and development

During tissue and organ development and maintenance, the dynamic regulation of cellular proliferation and differentiation allows cells to build highly elaborate structures. The development of the vertebrate retina or the maintenance of adult intestinal crypts, for instance, involves the arrangement of newly created cells with different phenotypes, the proportions of which need to be tightly controlled. While some of the basic principles underlying these processes developing and maintaining these organs are known, much remains to be learnt from how cells encode the necessary information and use it to attain those complex but reproducible arrangements. Here, we review the current knowledge on the principles underlying cell population dynamics during tissue development and homeostasis. In particular, we discuss how stochastic fate assignment, cell division, feedback control and cellular transition states interact during organ and tissue development and maintenance in multicellular organisms. We propose a framework, involving the existence of a transition state in which cells are more susceptible to signals that can affect their gene expression state and influence their cell fate decisions. This framework, which also applies to systems much more amenable to quantitative analysis like differentiating embryonic stem cells, links gene expression programmes with cell population dynamics.     

A yeast strain defective in oleic acid utilization has a mutation in the RML2 gene.

The molecular mechanisms of cellular long-chain fatty acid assimilation and its regulation remain unclear. In an attempt to identify essential mediators of these processes, we have isolated mutant strains of the yeast Saccharomyces cerevisiae unable to utilize oleic acid as sole carbon source, while retaining the ability to utilize acetate. These strains are then subjected to several secondary screening assays to identify mutants of interest. Here we describe a mutant (denoted fat21) that, despite a temperature-sensitive inability to utilize oleic acid as sole carbon source, displays no general defect in oleic acid uptake or incorporation of oleic acid into glycerolipids. Oxidation of acetate after growth in acetate medium is increased similarly in the mutant and parent strains. Oleic acid beta-oxidation in acetate grown cells is also comparable between strains. Induction of oleic acid oxidation following exposure to oleic acid is, however, defective in the fat21 mutant. The fat21 mutant allele displays conditional synthetic lethality in combination with a null allele of the OLE1 gene, which encodes Delta9-desaturase and is required for proper mitochondrial segregation. Clones capable of complementing the fat21 defect contained the RML2 gene, encoding a yeast mitochondria ribosomal protein. Segregation analysis and gene replacement experiments demonstrate that RML2 is the gene defective in the fat21 mutant. These observations of a defect in a mitochondrial protein differentially affecting the adaptation to oleic acid and acetate as carbon sources suggest that the phenotype of fat21 is associated with a novel pathway of mitochondrial-nuclear-peroxisomal communication.     

A well-characterized polycistronic-like gene expression system in yeast

Efficient expression of multiple genes is critical to yeast metabolic engineering for the bioproduction of bulk and fine chemicals. A yeast polycistronic expression system is of particular interest because one promoter can drive the expression of multiple genes. 2A viral peptides enable the cotranslation of multiple proteins from a single mRNA by ribosomal skipping. However, the wide adaptation of 2A viral peptides for polycistronic-like gene expression in yeast awaits in-depth characterizations. Additionally, a one-step assembly of such a polycistronic-like system is highly desirable. To this end, we have developed a modular cloning (MoClo) compatible 2A peptide-based polycistronic-like system capable of expressing multiple genes from a single promoter in yeast. Characterizing the bi-, tri-, and quad-cistronic expression of fluorescent proteins showed high cleavage efficiencies of three 2A peptides: E2A from equine rhinitis B virus, P2A from porcine teschovirus-1, and O2A from Operophtera brumata cypovirus-18. Applying the polycistronic-like system to produce geraniol, a valuable industrial compound, resulted in comparable or higher titers than using conventional monocistronic constructs. In summary, this highly-characterized polycistronic-like gene expression system is another tool to facilitate multigene expression for metabolic engineering in yeast.