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Mitochondrial Ribosomal Protein L12 Selectively Associates with Human Mitochondrial RNA Polymerase to Activate Transcription

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Mitochondrial Ribosomal Protein L12 Selectively Associates with Human Mitochondrial RNA Polymerase to Activate Transcription Mitochondrial Ribosomal Protein L12 selectively associates with human mitochondrial RNA polymerase to activate transcription Yulia V. Surovtsevaa, Timothy E. Shutta, Justin Cotneya, Huseyin Cimenb, Sophia Y. Chena, Emine C. Kocb, and Gerald S. Shadela,c,1 aDepartment of Pathology, Yale University School of Medicine, New Haven, CT 06520; cDepartment of Genetics, Yale University School of Medicine, New Haven, CT 06520; and bDepartment of Biochemistry and Molecular Biology, Pennsylvania State University, University Park, PA 16802 Edited* by Douglas C. Wallace, Children's Hospital of Philadelphia, Philadelphia, PA, and approved August 31, 2011 (received for review June 1, 2011) Basal transcription of human mitochondrial DNA (mtDNA) in vitro Based on in vitro studies, transcription of human mtDNA re- requires the single-subunit, bacteriophage-related RNA polymerase, quires a core two-component system (9): a single-subunit RNA POLRMT, and transcription factor h-mtTFB2. This two-component polymerase, POLRMT (10), and human mitochondrial transcrip- system is activated differentially at mtDNA promoters by human tion factor B2, h-mtTFB2 (or TFB2M) (11, 12). POLRMT, like its mitochondrial transcription factor A (h-mtTFA). Mitochondrial ribo- yeast homolog Rpo41p, is related to the bacteriophage T-odd somal protein L7/L12 (MRPL12) binds directly to POLRMT, but family of RNA polymerases (10, 13), but has a large N-terminal whether it does so in the context of the ribosome or as a “free” pro- extension that contains two pentatricopeptide repeats of unknown tein in the matrix is unknown. Furthermore, existing evidence that function (14). Relevant to this study, h-mtTFB2 is homologous to MRPL12 activates mitochondrial transcription derives from overex- the bacterial KsgA family of rRNA methyltransferases, an ortholog pression studies in cultured cells and transcription experiments using of which was inherited from the original bacterial endosymbiont crude mitochondrial lysates, precluding direct effects of MRPL12 on ancestor of mitochondria (15, 16). This core two-component sys- transcription to be assigned. Here, we report that depletion of tem is activated by the HMG-box transcription factor, h-mtTFA MRPL12 from HeLa cells by shRNA results in decreased steady-state (or TFAM) (17–19), that binds at the mtDNA promoters LSP BIOCHEMISTRY levels of mitochondrial transcripts, which are not accounted for by and HSP1 and interacts with h-mtTFB2 (20). The role of h-mtTFA “ ” changes in RNA stability. We also show that a significant free pool as a transcriptional activator is well documented, but it also has of MRPL12 exists in human mitochondria not associated with ribo- proposed roles in packaging (21–23) and repair (24) of mtDNA. “ ” somes. Free MRPL12 binds selectively to POLRMT in vivo in a com- A paralog of h-mtTFB2, h-mtTFB1 (or TFB1M), that was origin- plex distinct from those containing h-mtTFB2. Finally, using a fully ally characterized as a mitochondrial transcription factor in vitro recombinant mitochondrial transcription system, we demonstrate (11, 25), is the functional ortholog of the bacterial KsgA rRNA that MRPL12 stimulates promoter-dependent and promoter-inde- methyltransferase that dimethylates a conserved stem-loop in the pendent transcription directly in vitro. Based on these results, we mitochondrial 12S rRNA (26) and, hence, has a conserved func- propose that, when not associated with ribosomes, MRPL12 has tion in mitochondrial ribosome biogenesis (27) and translation a second function in transcription, perhaps acting to facilitate the (8, 12, 28) in vivo. That h-mtTFB1 and h-mtTFB2 are derived from transition from initiation to elongation. We speculate that this is an rRNA methyltransferase, suggests a long evolutionary linkage one mechanism to coordinate mitochondrial ribosome biogenesis between mitochondrial proteins involved in transcription, transla- and transcription in human mitochondria, where transcription of tion, and ribosome biogenesis. rRNAs from the mtDNA presumably needs to be adjusted in accor- Transcription and translation are functionally linked in yeast dance with the rate of import and assembly of the nucleus-encoded mitochondria, where Nam1p and Sls1p bind to the N-terminal MRPs into ribosomes. domain of mitochondrial RNA polymerase and couple transcrip- tion and translation activities (14, 29–31), presumably by delivering TFAM ∣ TFB2M ∣ translation ∣ oxidative phosphorylation ∣ gene expression newly synthesized mRNAs to translation factors and ribosomes as- sociated with the inner mitochondrial membrane (32, 33). Whether itochondria are dynamic cellular organelles that contain these events occur cotranscriptionally in yeast mitochondria is not DNA (mtDNA). In mammals, mtDNA is maternally inher- M known and, because no homologs of Nam1p and Sls1p have been ited and essential because it encodes genes required for oxidative identified in mammals, evidence for similar coupling mechanisms phosphorylation. For example, human mtDNA is a 16,569 base- in mammalian mitochondria has not surfaced. pair, double-stranded, circular molecule harboring thirty-seven The mammalian 55S mitochondrial ribosomes comprise asso- genes: thirteen mRNAs, two rRNAs, and twenty-two tRNAs (1). ciated large (39S) and small (28S) ribosomal subunits (4, 5). In The remaining ∼1;500 proteins in mitochondria (2) are nuclear gene products that are imported into the organelle, including addition to their rRNA subunits, the large and small ribosomal many required for expression and replication of mtDNA (3). As subunits are each composed of multiple MRPs. We identified one example, the dedicated set of mitochondrial ribosomes (en- previously that MRPL7/L12 (referred to as MRPL12 from this tirely distinct from those in the cytoplasm) that translates the point forward) binds directly to POLRMT and modulates mito- mtDNA-encoded mRNAs comprise ∼80 mitochondrial riboso- chondrial gene expression when overexpressed in HeLa cells (34), mal proteins (MRPs) that are all products of nuclear genes and imported into the mitochondrial matrix to associate with the two Author contributions: Y.V.S., T.E.S., J.C., H.C., E.C.K., and G.S.S. designed research; Y.V.S., mtDNA-encoded rRNAs (4–7). Thus, ribosome biogenesis is T.E.S., J.C., H.C., and S.Y.C. performed research; Y.V.S., E.C.K., and G.S.S. analyzed data; unique in mitochondria in that the protein and RNA subunits are and Y.V.S. and G.S.S. wrote the paper. encoded by two genomes. How transcription and processing of The authors declare no conflict of interest. the rRNAs in the matrix is coordinated with nuclear gene expres- *This Direct Submission article had a prearranged editor. sion and import of the MRPs for ribosome assembly is largely 1To whom correspondence should be addressed. E-mail: [email protected]. unknown, but may be a unique control point for mitochondrial This article contains supporting information online at www.pnas.org/lookup/suppl/ gene expression and/or overall mitochondrial biogenesis (8). doi:10.1073/pnas.1108852108/-/DCSupplemental. www.pnas.org/cgi/doi/10.1073/pnas.1108852108 PNAS Early Edition ∣ 1of6 Downloaded by guest on October 1, 2021 providing a functional link between mitochondrial ribosomes/ state levels of several other MRPs analyzed were unchanged in translation and transcription in human mitochondria. Here we MRPL12 knockdown cells 7 d after MRPL12 depletion (Fig. S1A). have investigated this link further and conclude, based on both Moreover, sucrose density fractionation of mitochondrial ribo- in vivo and in vitro evidence, that it is a “free” pool of MRPL12 somes revealed that overall ribosome assembly was not signifi- (i.e., not associated with assembled ribosomes) that interacts with cantly affected in MRPL12 knockdown cells compared to negative POLRMT to directly activate mitochondrial transcription. These controls (Fig. S1B). These data, coupled with the known interac- results provide significant insight into the mechanism of human tion with POLRMT, suggested to us that the observed effects of mitochondrial gene expression, as well as the proposed dual-func- MRPL12 on mtDNA-encoded protein expression may involve tion nature of several MRPs. not only its function in ribosomes and translation, but also a role for MRPL12 in transcription. Results To examine this possibility, we next measured the steady-state Human MRPL12 Positively Regulates Mitochondrial Transcription and level of mitochondrial transcripts in MRPL12 knockdown cell Translation In Vivo, without Grossly Affecting Ribosome Biogenesis. lines by quantitative real-time RT-PCR and observed a significant We showed previously that MRPL12 interacts with POLRMT decrease in ND1, COII, and ND6 (representing mRNAs encoded in vitro and increases mitochondrial transcript levels when over- on both strands of mtDNA) as well as 12S and 16S mitochondrial expressed in HeLa cells (34). To investigate further the role of rRNAs (Fig. 2A). Similar results were obtained when MRPL12 MRPL12 in mitochondrial gene expression in vivo, we knocked was knocked down in a HeLa cell line that expresses HA-tagged it down using lentiviral-induced shRNA in HeLa and HEK293T A B cells. Western blot analysis revealed that three different shRNA POLRMT (Fig. S2 and ). This effect was specific to depletion constructs efficiently reduced MRPL12 compared to negative- of MRPL12 because knockdown of another mitochondrial ribo- control GFP shRNA-infected cells (Fig. 1A). As predicted from somal protein, MRPS10, did not cause any significant
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