Claes M Gustafsson

Publications (59)558.82 Total impact

• Article: Emerging roles of Cdk8 in cell cycle control.

  Zsolt Szilagyi, Claes M Gustafsson
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  ABSTRACT: Cyclin dependent kinase 8 (Cdk8) is a component of Mediator, an evolutionary conserved multiprotein complex that regulates RNA polymerase II-dependent transcription. Cdk8 has been implicated as a regulator of multiple steps in cell cycle progression. We here discuss recent advances in our understanding of Cdk8 function and a possible role for Mediator as a hub for integrating transcription regulation with cell cycle progression.
  Biochimica et Biophysica Acta 05/2013; · 4.66 Impact Factor
• Article: MTERF1 Binds mtDNA to Prevent Transcriptional Interference at the Light-Strand Promoter but Is Dispensable for rRNA Gene Transcription Regulation.

  Mügen Terzioglu, Benedetta Ruzzenente, Julia Harmel, Arnaud Mourier, Elisabeth Jemt, Marcela Dávila López, Christian Kukat, James B Stewart, Rolf Wibom, Caroline Meharg, Bianca Habermann, Maria Falkenberg, Claes M Gustafsson, Chan Bae Park, Nils-Göran Larsson
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  ABSTRACT: Mitochondrial transcription termination factor 1, MTERF1, has been reported to couple rRNA gene transcription initiation with termination and is therefore thought to be a key regulator of mammalian mitochondrial ribosome biogenesis. The prevailing model is based on a series of observations published over the last two decades, but no in vivo evidence exists to show that MTERF1 regulates transcription of the heavy-strand region of mtDNA containing the rRNA genes. Here, we demonstrate that knockout of Mterf1 in mice has no effect on mitochondrial rRNA levels or mitochondrial translation. Instead, loss of Mterf1 influences transcription initiation at the light-strand promoter, resulting in a decrease of de novo transcription manifested as reduced 7S RNA levels. Based on these observations, we suggest that MTERF1 does not regulate heavy-strand transcription, but rather acts to block transcription on the opposite strand of mtDNA to prevent transcription interference at the light-strand promoter.
  Cell metabolism 04/2013; 17(4):618-26. · 17.35 Impact Factor
• Source

  Available from: Sjoerd Wanrooij

  Article: In vivo mutagenesis reveals that OriL is essential for mitochondrial DNA replication.

  Sjoerd Wanrooij, Javier Miralles Fusté, James B Stewart, Paulina H Wanrooij, Tore Samuelsson, Nils-Göran Larsson, Claes M Gustafsson, Maria Falkenberg
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  ABSTRACT: The mechanisms of mitochondrial DNA replication have been hotly debated for a decade. The strand-displacement model states that lagging-strand DNA synthesis is initiated from the origin of light-strand DNA replication (OriL), whereas the strand-coupled model implies that OriL is dispensable. Mammalian mitochondria cannot be transfected and the requirements of OriL in vivo have therefore not been addressed. We here use in vivo saturation mutagenesis to demonstrate that OriL is essential for mtDNA maintenance in the mouse. Biochemical and bioinformatic analyses show that OriL is functionally conserved in vertebrates. Our findings strongly support the strand-displacement model for mtDNA replication.
  EMBO Reports 10/2012; · 7.36 Impact Factor
• Source

  Available from: Sjoerd Wanrooij

  Article: Mammalian transcription factor A is a core component of the mitochondrial transcription machinery.

  Yonghong Shi, Anke Dierckx, Paulina H Wanrooij, Sjoerd Wanrooij, Nils-Göran Larsson, L Marcus Wilhelmsson, Maria Falkenberg, Claes M Gustafsson
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  ABSTRACT: Transcription factor A (TFAM) functions as a DNA packaging factor in mammalian mitochondria. TFAM also binds sequence-specifically to sites immediately upstream of mitochondrial promoters, but there are conflicting data regarding its role as a core component of the mitochondrial transcription machinery. We here demonstrate that TFAM is required for transcription in mitochondrial extracts as well as in a reconstituted in vitro transcription system. The absolute requirement of TFAM can be relaxed by conditions that allow DNA breathing, i.e., low salt concentrations or negatively supercoiled DNA templates. The situation is thus very similar to that described in nuclear RNA polymerase II-dependent transcription, in which the free energy of supercoiling can circumvent the need for a subset of basal transcription factors at specific promoters. In agreement with these observations, we demonstrate that TFAM has the capacity to induce negative supercoils in DNA, and, using the recently developed nucleobase analog FRET-pair tC(O)-tC(nitro), we find that TFAM distorts significantly the DNA structure. Our findings differ from recent observations reporting that TFAM is not a core component of the mitochondrial transcription machinery. Instead, our findings support a model in which TFAM is absolutely required to recruit the transcription machinery during initiation of transcription.
  Proceedings of the National Academy of Sciences 09/2012; 109(41):16510-5. · 9.68 Impact Factor
• Article: A hybrid G-quadruplex structure formed between RNA and DNA explains the extraordinary stability of the mitochondrial R-loop.

  Paulina H Wanrooij, Jay P Uhler, Yonghong Shi, Fredrik Westerlund, Maria Falkenberg, Claes M Gustafsson
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  ABSTRACT: In human mitochondria the transcription machinery generates the RNA primers needed for initiation of DNA replication. A critical feature of the leading-strand origin of mitochondrial DNA replication is a CG-rich element denoted conserved sequence block II (CSB II). During transcription of CSB II, a G-quadruplex structure forms in the nascent RNA, which stimulates transcription termination and primer formation. Previous studies have shown that the newly synthesized primers form a stable and persistent RNA-DNA hybrid, a R-loop, near the leading-strand origin of DNA replication. We here demonstrate that the unusual behavior of the RNA primer is explained by the formation of a stable G-quadruplex structure, involving the CSB II region in both the nascent RNA and the non-template DNA strand. Based on our data, we suggest that G-quadruplex formation between nascent RNA and the non-template DNA strand may be a regulated event, which decides the fate of RNA primers and ultimately the rate of initiation of DNA synthesis in human mitochondria.
  Nucleic Acids Research 09/2012; · 8.03 Impact Factor
• Article: Structure of the human MTERF4-NSUN4 protein complex that regulates mitochondrial ribosome biogenesis.

  Henrik Spåhr, Bianca Habermann, Claes M Gustafsson, Nils-Göran Larsson, B Martin Hallberg
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  ABSTRACT: Proteins crucial for the respiratory chain are translated by the mitochondrial ribosome. Mitochondrial ribosome biogenesis is therefore critical for oxidative phosphorylation capacity and disturbances are known to cause human disease. This complex process is evolutionary conserved and involves several RNA processing and modification steps required for correct ribosomal RNA maturation. We recently showed that a member of the mitochondrial transcription termination factor (MTERF) family of proteins, MTERF4, recruits NSUN4, a 5-methylcytosine RNA methyltransferase, to the large ribosomal subunit in a process crucial for mitochondrial ribosome biogenesis. Here, we describe the 3D crystal structure of the human MTERF4-NSUN4 complex determined to 2.9 Å resolution. MTERF4 is composed of structurally repeated MTERF-motifs that form a nucleic acid binding domain. NSUN4 lacks an N- or C-terminal extension that is commonly used for RNA recognition by related RNA methyltransferases. Instead, NSUN4 binds to the C-terminus of MTERF4. A positively charged surface forms an RNA binding path from the concave to the convex side of MTERF4 and further along NSUN4 all of the way into the active site. This finding suggests that both subunits of the protein complex likely contribute to RNA recognition. The interface between MTERF4 and NSUN4 contains evolutionarily conserved polar and hydrophobic amino acids, and mutations that change these residues completely disrupt complex formation. This study provides a molecular explanation for MTERF4-dependent recruitment of NSUN4 to ribosomal RNA and suggests a unique mechanism by which other members of the large MTERF-family of proteins can regulate ribosomal biogenesis.
  Proceedings of the National Academy of Sciences 09/2012; 109(38):15253-8. · 9.68 Impact Factor
• Article: Protein sliding and DNA denaturation are essential for DNA organization by human mitochondrial transcription factor A.

  Géraldine Farge, Niels Laurens, Onno D Broekmans, Siet M J L van den Wildenberg, Linda C M Dekker, Martina Gaspari, Claes M Gustafsson, Erwin J G Peterman, Maria Falkenberg, Gijs J L Wuite
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  ABSTRACT: Mitochondria organize their genome in protein-DNA complexes called nucleoids. The mitochondrial transcription factor A (TFAM), a protein that regulates mitochondrial transcription, is abundant in these nucleoids. TFAM is believed to be essential for mitochondrial DNA compaction, yet the exact mechanism has not been resolved. Here we use a combination of single-molecule manipulation and fluorescence microscopy to show the nonspecific DNA-binding dynamics and compaction by TFAM. We observe that single TFAM proteins diffuse extensively over DNA (sliding) and, by collisions, form patches on DNA in a cooperative manner. Moreover, we demonstrate that TFAM induces compaction by changing the flexibility of the DNA, which can be explained by local denaturation of the DNA (melting). Both sliding of TFAM and DNA melting are also necessary characteristics for effective, specific transcription regulation by TFAM. This apparent connection between transcription and DNA organization clarifies how TFAM can accomplish two complementary roles in the mitochondrial nucleoid at the same time.
  Nature Communications 08/2012; 3:1013. · 7.40 Impact Factor
• Article: Mediator Promotes CENP-A Incorporation at Fission Yeast Centromeres.

  Jonas O Carlsten, Zsolt Szilagyi, Beidong Liu, Marcela Davila Lopez, Erzsébet Szászi, Ingela Djupedal, Thomas Nyström, Karl Ekwall, Claes M Gustafsson, Xuefeng Zhu
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  ABSTRACT: At Schizosaccharomyces pombe centromeres, heterochromatin formation is required for de novo incorporation of the histone H3 variant CENP-A(Cnp1), which in turn directs kinetochore assembly and ultimately chromosome segregation during mitosis. Noncoding RNAs (ncRNAs) transcribed by RNA polymerase II (Pol II) directs heterochromatin formation through not only the RNA interference (RNAi) machinery but also RNAi-independent RNA processing factors. Control of centromeric ncRNA transcription is therefore a key factor for proper centromere function. We here demonstrate that Mediator directs ncRNA transcription and regulates centromeric heterochromatin formation in fission yeast. Mediator colocalizes with Pol II at centromeres, and loss of the Mediator subunit Med20 causes a dramatic increase in pericentromeric transcription and desilencing of the core centromere. As a consequence, heterochromatin formation is impaired via both the RNAi-dependent and -independent pathways, resulting in loss of CENP-A(Cnp1) from the core centromere, a defect in kinetochore function, and a severe chromosome segregation defect. Interestingly, the increased centromeric transcription observed in med20Δ cells appears to directly block CENP-A(Cnp1) incorporation since inhibition of Pol II transcription can suppress the observed phenotypes. Our data thus identify Mediator as a crucial regulator of ncRNA transcription at fission yeast centromeres and add another crucial layer of regulation to centromere function.
  Molecular and cellular biology 07/2012; 32(19):4035-43. · 6.06 Impact Factor
• Article: Cyclin-dependent kinase 8 regulates mitotic commitment in fission yeast.

  Zsolt Szilagyi, Gabor Banyai, Marcela Davila Lopez, Christopher J McInerny, Claes M Gustafsson
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  ABSTRACT: Temporal changes in transcription programs are coupled to control of cell growth and division. We here report that Mediator, a conserved coregulator of eukaryotic transcription, is part of a regulatory pathway that controls mitotic entry in fission yeast. The Mediator subunit cyclin-dependent kinase 8 (Cdk8) phosphorylates the forkhead 2 (Fkh2) protein in a periodic manner that coincides with gene activation during mitosis. Phosphorylation prevents degradation of the Fkh2 transcription factor by the proteasome, thus ensuring cell cycle-dependent variations in Fkh2 levels. Interestingly, Cdk8-dependent phosphorylation of Fkh2 controls mitotic entry, and mitotic entry is delayed by inactivation of the Cdk8 kinase activity or mutations replacing the phosphorylated serine residues of Fkh2. In addition, mutations in Fkh2, which mimic protein phosphorylation, lead to premature mitotic entry. Therefore, Fkh2 regulates not only the onset of mitotic transcription but also the correct timing of mitotic entry via effects on the Wee1 kinase. Our findings thus establish a new pathway linking the Mediator complex to control of mitotic transcription and regulation of mitotic entry in fission yeast.
  Molecular and cellular biology 03/2012; 32(11):2099-109. · 6.06 Impact Factor
• Source

  Available from: Metodi D Metodiev

  Article: LRPPRC is necessary for polyadenylation and coordination of translation of mitochondrial mRNAs.

  Benedetta Ruzzenente, Metodi D Metodiev, Anna Wredenberg, Ana Bratic, Chan Bae Park, Yolanda Cámara, Dusanka Milenkovic, Volker Zickermann, Rolf Wibom, Kjell Hultenby, Hediye Erdjument-Bromage, Paul Tempst, Ulrich Brandt, James B Stewart, Claes M Gustafsson, Nils-Göran Larsson
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  ABSTRACT: Regulation of mtDNA expression is critical for maintaining cellular energy homeostasis and may, in principle, occur at many different levels. The leucine-rich pentatricopeptide repeat containing (LRPPRC) protein regulates mitochondrial mRNA stability and an amino-acid substitution of this protein causes the French-Canadian type of Leigh syndrome (LSFC), a neurodegenerative disorder characterized by complex IV deficiency. We have generated conditional Lrpprc knockout mice and show here that the gene is essential for embryonic development. Tissue-specific disruption of Lrpprc in heart causes mitochondrial cardiomyopathy with drastic reduction in steady-state levels of most mitochondrial mRNAs. LRPPRC forms an RNA-dependent protein complex that is necessary for maintaining a pool of non-translated mRNAs in mammalian mitochondria. Loss of LRPPRC does not only decrease mRNA stability, but also leads to loss of mRNA polyadenylation and the appearance of aberrant mitochondrial translation. The translation pattern without the presence of LRPPRC is misregulated with excessive translation of some transcripts and no translation of others. Our findings point to the existence of an elaborate machinery that regulates mammalian mtDNA expression at the post-transcriptional level.
  The EMBO Journal 11/2011; 31(2):443-56. · 9.20 Impact Factor
• Article: Adenosine kinase deficiency disrupts the methionine cycle and causes hypermethioninemia, encephalopathy, and abnormal liver function.

  Magnus K Bjursell, Henk J Blom, Jordi Asin Cayuela, Martin L Engvall, Nicole Lesko, Shanti Balasubramaniam, Göran Brandberg, Maria Halldin, Maria Falkenberg, Cornelis Jakobs, Desiree Smith, Eduard Struys, Ulrika von Döbeln, Claes M Gustafsson, Joakim Lundeberg, Anna Wedell
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  ABSTRACT: Four inborn errors of metabolism (IEMs) are known to cause hypermethioninemia by directly interfering with the methionine cycle. Hypermethioninemia is occasionally discovered incidentally, but it is often disregarded as an unspecific finding, particularly if liver disease is involved. In many individuals the hypermethioninemia resolves without further deterioration, but it can also represent an early sign of a severe, progressive neurodevelopmental disorder. Further investigation of unclear hypermethioninemia is therefore important. We studied two siblings affected by severe developmental delay and liver dysfunction. Biochemical analysis revealed increased plasma levels of methionine, S-adenosylmethionine (AdoMet), and S-adenosylhomocysteine (AdoHcy) but normal or mildly elevated homocysteine (Hcy) levels, indicating a block in the methionine cycle. We excluded S-adenosylhomocysteine hydrolase (SAHH) deficiency, which causes a similar biochemical phenotype, by using genetic and biochemical techniques and hypothesized that there was a functional block in the SAHH enzyme as a result of a recessive mutation in a different gene. Using exome sequencing, we identified a homozygous c.902C>A (p.Ala301Glu) missense mutation in the adenosine kinase gene (ADK), the function of which fits perfectly with this hypothesis. Increased urinary adenosine excretion confirmed ADK deficiency in the siblings. Four additional individuals from two unrelated families with a similar presentation were identified and shown to have a homozygous c.653A>C (p.Asp218Ala) and c.38G>A (p.Gly13Glu) mutation, respectively, in the same gene. All three missense mutations were deleterious, as shown by activity measurements on recombinant enzymes. ADK deficiency is a previously undescribed, severe IEM shedding light on a functional link between the methionine cycle and adenosine metabolism.
  The American Journal of Human Genetics 09/2011; 89(4):507-15. · 10.60 Impact Factor
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  Available from: PubMed Central

  Article: The mitochondrial DNA helicase TWINKLE can assemble on a closed circular template and support initiation of DNA synthesis.

  Elisabeth Jemt, Géraldine Farge, Stefan Bäckström, Teresa Holmlund, Claes M Gustafsson, Maria Falkenberg
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  ABSTRACT: Mitochondrial DNA replication is performed by a simple machinery, containing the TWINKLE DNA helicase, a single-stranded DNA-binding protein, and the mitochondrial DNA polymerase γ. In addition, mitochondrial RNA polymerase is required for primer formation at the origins of DNA replication. TWINKLE adopts a hexameric ring-shaped structure that must load on the closed circular mtDNA genome. In other systems, a specialized helicase loader often facilitates helicase loading. We here demonstrate that TWINKLE can function without a specialized loader. We also show that the mitochondrial replication machinery can assemble on a closed circular DNA template and efficiently elongate a DNA primer in a manner that closely resembles initiation of mtDNA synthesis in vivo.
  Nucleic Acids Research 08/2011; 39(21):9238-49. · 8.03 Impact Factor
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  Available from: PubMed Central

  Article: Histone modifications influence mediator interactions with chromatin.

  Xuefeng Zhu, Yongqiang Zhang, Gudrun Bjornsdottir, Zhongle Liu, Amy Quan, Michael Costanzo, Marcela Dávila López, Jakub Orzechowski Westholm, Hans Ronne, Charles Boone, Claes M Gustafsson, Lawrence C Myers
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  ABSTRACT: The Mediator complex transmits activation signals from DNA bound transcription factors to the core transcription machinery. Genome wide localization studies have demonstrated that Mediator occupancy not only correlates with high levels of transcription, but that the complex also is present at transcriptionally silenced locations. We provide evidence that Mediator localization is guided by an interaction with histone tails, and that this interaction is regulated by their post-translational modifications. A quantitative, high-density genetic interaction map revealed links between Mediator components and factors affecting chromatin structure, especially histone deacetylases. Peptide binding assays demonstrated that pure wild-type Mediator forms stable complexes with the tails of Histone H3 and H4. These binding assays also showed Mediator-histone H4 peptide interactions are specifically inhibited by acetylation of the histone H4 lysine 16, a residue critical in transcriptional silencing. Finally, these findings were validated by tiling array analysis that revealed a broad correlation between Mediator and nucleosome occupancy in vivo, but a negative correlation between Mediator and nucleosomes acetylated at histone H4 lysine 16. Our studies show that chromatin structure and the acetylation state of histones are intimately connected to Mediator localization.
  Nucleic Acids Research 07/2011; 39(19):8342-54. · 8.03 Impact Factor
• Article: Mediator influences telomeric silencing and cellular life span.

  Xuefeng Zhu, Beidong Liu, Jonas O P Carlsten, Jenny Beve, Thomas Nyström, Lawrence C Myers, Claes M Gustafsson
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  ABSTRACT: The Mediator complex is required for the regulated transcription of nearly all RNA polymerase II-dependent genes. Here we demonstrate a new role for Mediator which appears to be separate from its function as a transcriptional coactivator. Mediator associates directly with heterochromatin at telomeres and influences the exact boundary between active and inactive chromatin. Loss of the Mediator Med5 subunit or mutations in Med7 cause a depletion of the complex from regions located near subtelomeric X elements, which leads to a change in the balance between the Sir2 and Sas2 proteins. These changes in turn result in increased levels of H4K16 acetylation near telomeres and in desilencing of subtelomeric genes. Increases in H4K16 acetylation have been observed at telomeres in aging cells. In agreement with this observation, we found that the loss of MED5 leads to shortening of the Saccharomyces cerevisiae (budding yeast) replicative life span.
  Molecular and cellular biology 06/2011; 31(12):2413-21. · 6.06 Impact Factor
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  Available from: Metodi D Metodiev

  Article: MTERF4 regulates translation by targeting the methyltransferase NSUN4 to the mammalian mitochondrial ribosome.

  Yolanda Cámara, Jorge Asin-Cayuela, Chan Bae Park, Metodi D Metodiev, Yonghong Shi, Benedetta Ruzzenente, Christian Kukat, Bianca Habermann, Rolf Wibom, Kjell Hultenby, Thomas Franz, Hediye Erdjument-Bromage, Paul Tempst, B Martin Hallberg, Claes M Gustafsson, Nils-Göran Larsson
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  ABSTRACT: Precise control of mitochondrial DNA gene expression is critical for regulation of oxidative phosphorylation capacity in mammals. The MTERF protein family plays a key role in this process, and its members have been implicated in regulation of transcription initiation and site-specific transcription termination. We now demonstrate that a member of this family, MTERF4, directly controls mitochondrial ribosomal biogenesis and translation. MTERF4 forms a stoichiometric complex with the ribosomal RNA methyltransferase NSUN4 and is necessary for recruitment of this factor to the large ribosomal subunit. Loss of MTERF4 leads to defective ribosomal assembly and a drastic reduction in translation. Our results thus show that MTERF4 is an important regulator of translation in mammalian mitochondria.
  Cell metabolism 05/2011; 13(5):527-39. · 17.35 Impact Factor
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  Available from: PubMed Central

  Article: Maintenance of respiratory chain function in mouse hearts with severely impaired mtDNA transcription.

  Christoph Freyer, Chan Bae Park, Mats I Ekstrand, Yonghong Shi, Julia Khvorostova, Rolf Wibom, Maria Falkenberg, Claes M Gustafsson, Nils-Göran Larsson
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  ABSTRACT: The basal mitochondrial transcription machinery is essential for biogenesis of the respiratory chain and consists of mitochondrial RNA polymerase, mitochondrial transcription factor A (TFAM) and mitochondrial transcription factor B2. This triad of proteins is sufficient and necessary for mtDNA transcription initiation. Abolished mtDNA transcription caused by tissue-specific knockout of TFAM in the mouse heart leads to early onset of a severe mitochondrial cardiomyopathy with lethality within the first post-natal weeks. Here, we describe a mouse model expressing human TFAM instead of the endogenous mouse TFAM in heart. These rescue mice have severe reduction in mtDNA transcription initiation, but, surprisingly, are healthy at the age of 52 weeks with near-normal steady-state levels of transcripts. In addition, we demonstrate that heavy-strand mtDNA transcription normally terminates at the termination-associated sequence in the control region. This termination is abolished in rescue animals resulting in heavy (H)-strand transcription of the entire control region. In conclusion, we demonstrate here the existence of an unexpected mtDNA transcript stabilization mechanism that almost completely compensates for the severely reduced transcription initiation in rescue hearts. Future elucidation of the underlying molecular mechanism may provide a novel pathway to treat mitochondrial dysfunction in human pathology.
  Nucleic Acids Research 10/2010; 38(19):6577-88. · 8.03 Impact Factor
• Article: A chromatin-remodeling protein is a component of fission yeast mediator.

  Olga Khorosjutina, Paulina H Wanrooij, Julian Walfridsson, Zsolt Szilagyi, Xuefeng Zhu, Vera Baraznenok, Karl Ekwall, Claes M Gustafsson
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  ABSTRACT: The multiprotein Mediator complex is an important regulator of RNA polymerase II-dependent genes in eukaryotic cells. In contrast to the situation in many other eukaryotes, the conserved Med15 protein is not a stable component of Mediator isolated from fission yeast. We here demonstrate that Med15 exists in a protein complex together with Hrp1, a CHD1 ATP-dependent chromatin-remodeling protein. The Med15-Hrp1 subcomplex is not a component of the core Mediator complex but can interact with the L-Mediator conformation. Deletion of med15(+) and hrp1(+) causes very similar effects on global steady-state levels of mRNA, and genome-wide analyses demonstrate that Med15 associates with a distinct subset of Hrp1-bound gene promoters. Our findings therefore indicate that Mediator may directly influence histone density at regulated promoters.
  Journal of Biological Chemistry 09/2010; 285(39):29729-37. · 4.77 Impact Factor
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  Available from: pnas.org

  Article: G-quadruplex structures in RNA stimulate mitochondrial transcription termination and primer formation.

  Paulina H Wanrooij, Jay P Uhler, Tomas Simonsson, Maria Falkenberg, Claes M Gustafsson
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  ABSTRACT: The human mitochondrial transcription machinery generates the primers required for initiation of leading-strand DNA replication. According to one model, the 3' end of the primer is defined by transcription termination at conserved sequence block II (CSB II) in the mitochondrial DNA control region. We here demonstrate that this site-specific termination event is caused by G-quadruplex structures formed in nascent RNA upon transcription of CSB II. We also demonstrate that a poly-dT stretch downstream of CSB II has a modest stimulatory effect on the termination efficiency. The mechanism is reminiscent of Rho-independent transcription termination in prokaryotes, with the exception that a G-quadruplex structure replaces the hairpin loop formed in bacterial mRNA during transcription of terminator sequences.
  Proceedings of the National Academy of Sciences 09/2010; 107(37):16072-7. · 9.68 Impact Factor
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  Available from: Tore Samuelsson

  Article: LRPPRC is a mitochondrial matrix protein that is conserved in metazoans.

  Fredrik H Sterky, Benedetta Ruzzenente, Claes M Gustafsson, Tore Samuelsson, Nils-Göran Larsson
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  ABSTRACT: LRPPRC (also called LRP130) is an RNA-binding pentatricopeptide repeat protein. LRPPRC has been recognized as a mitochondrial protein, but has also been shown to regulate nuclear gene transcription and to bind specific RNA molecules in both the nucleus and the cytoplasm. We here present a bioinformatic analysis of the LRPPRC primary sequence, which reveals that orthologs to the LRPPRC gene are restricted to metazoan cells and that all of the corresponding proteins contain mitochondrial targeting signals. To address the subcellular localization further, we have carefully analyzed LRPPRC in mammalian cells and identified a single isoform that is exclusively localized to mitochondria. The LRPPRC protein is imported to the mitochondrial matrix and its mitochondrial targeting sequence is cleaved upon entry.
  Biochemical and Biophysical Research Communications 08/2010; 398(4):759-64. · 2.48 Impact Factor
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  Available from: mpg.de

  Article: MTERF1 gives mtDNA an unusual twist.

  Claes M Gustafsson, Nils-Göran Larsson
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  ABSTRACT: Expression of mtDNA is critical for biogenesis of the oxidative phosphorylation system, but the regulatory processes are poorly understood. Recent work in Cell (Yakubovskaya et al., 2010) reports a novel DNA-binding fold in mitochondrial transcription termination factor 1 (MTERF1), which causes unwinding and base eversion at its target mtDNA sequence.
  Cell metabolism 07/2010; 12(1):3-4. · 17.35 Impact Factor