Project description:Mitochondrial biogenesis relies on both the nuclear and mitochondrial genomes, and imbalance in their expression can lead to inborn errors of metabolism, inflammation, and aging. Here, we investigate N6AMT1, a nucleo-cytosolic methyltransferase that exhibits genetic codependency with mitochondria. We determine transcriptional and translational profiles of N6AMT1 and report that it is required for the cytosolic translation of TRMT10C (MRPP1) and PRORP (MRPP3), two subunits of the mitochondrial RNAse P enzyme. In the absence of N6AMT1, or when its catalytic activity is abolished, RNA processing within mitochondria is impaired, leading to the accumulation of unprocessed and double-stranded RNA, thus preventing mitochondrial protein synthesis and oxidative phosphorylation, and leading to an immune response. Our work sheds light on the function of N6AMT1 in protein synthesis and highlights a cytosolic program required for proper mitochondrial biogenesis.

Project description:Mitochondrial biogenesis relies on both the nuclear and the mitochondrial genomes, and the mechanisms that support their coordinated expression are not fully understood. Improper mitochondrial DNA expression can lead to inborn error of metabolism, inflammation, and aging. Here, we investigate N6AMT1, a nucleo-cytosolic multi-substrate methyltransferase. We analyze genetic dependency, transcription, translation, and proteomic profiles of N6AMT1-depleted cells and report that N6AMT1 is necessary for the cytosolic translation of factors involved in mitochondrial RNA metabolism, including subunits of the mitochondrial RNase P. In the absence of N6AMT1, RNA processing and translation within mitochondria are impaired, while double-stranded RNA accumulates in mitochondrial RNA granules causing an interferon response. Our work highlights a cytosolic program required for proper mitochondrial biogenesis, with consequences on innate immunity.

Project description:Cytosolic N6AMT1-dependent translation supports mitochondrial RNA processing [RNA-Seq]

Project description:Cytosolic N6AMT1-dependent translation supports mitochondrial RNA processing [Ribo-seq]

Project description:In animals the organization of the compact mitochondrial genome and lack of introns have necessitated a unique mechanism for RNA processing. To date the regulation of mitochondrial RNA processing and its importance for ribosome biogenesis and energy metabolism are not clear. To understand the in vivo role of the endoribonuclease component of the RNase P complex, MRPP3, we created conditional knockout mice. Here we show that MRPP3 is essential for life, and heart and skeletal muscle-specific knockout leads to a cardiomyopathy early in life, indicating that it is the only RNase P enzyme in mitochondria. We show that RNA processing is required for the biogenesis of the respiratory chain and mitochondrial function. Transcriptome-wide parallel analyses of RNA ends (PARE) and RNA-Seq enabled us to identify the in vivo cleavage sites of RNase P. Cleavage of the 5′ tRNA ends precedes 3′ end processing in vivo and is required for the correct biogenesis of the mitochondrial ribosomal subunits and mitoribosomal proteins that are differentially stabilized or degraded in the absence of mature rRNAs. Finally we identify that large mitoribosomal proteins can form a subcomplex on a precursor mt-RNA containing the 16S rRNA indicating that mitoribosomal biogenesis proceeds co-transcriptionally. Taken together our data show that RNA processing links transcription to translation via assembly of the mitoribosome. Total RNA was isolated from heart tissue from 11 week old control (Mrpp3loxP/loxP) and Mrpp3 knockout mice (Mrpp3loxP/loxP, +/Ckmm), TruSeq libraries produced in triplicate, sequenced and analysed for differential expression. Mitochondrial RNA was isolated from heart tissue from 11 week old control (Mrpp3loxP/loxP) and Mrpp3 knockout mice (Mrpp3loxP/loxP, +/Ckmm), PARE libraries produced in triplicate and sequenced for analysis of mitochondrial RNA processing.

Project description:Background: DNA N6-methyladenosine (6mA) as a novel epigenetic signaling modification in humans and has been implicated in progression and tumorigenesis of several cancers. However, the function and mechanisms of 6mA in breast cancer (BC), the most common cancer among women, are unclear. Methods: The clinical role of 6mA was investigated by immunohistochemical (IHC) staining and Kaplan-Meier analysis of BC and their normal tissues. 6mA immunoprecipitation (IP) sequencing, mRNA sequencing and bioinformatics analysis were used to screen and validate the direct targets of 6mA. Results: Decreases in N6AMT1 correlated with the extent of 6mA in BC tissues and predicted a worse overall survival of BC patients. Knockdown N6AMT1 markedly reduced 6mA in DNA and promoted the proliferation and migration of BC in vivo and in vitro, whereas overexpression of N6AMT1 had the opposite effect, indicating N6AMT1 is a functional methyltransferase for DNA 6mA and relates with gene transcription. Critical negative regulators of the cell cycle, such as RB1, P21, REST and TP53 were identified as targets of N6AMT1 in BC. Conclusion: These results suggest N6AMT1 enhances DNA 6mA levels to repress tumor progression via transcriptional regulation of cell cycle inhibitors.

Project description:Background: DNA N6-methyladenosine (6mA) as a novel epigenetic signaling modification in humans and has been implicated in progression and tumorigenesis of several cancers. However, the function and mechanisms of 6mA in breast cancer (BC), the most common cancer among women, are unclear. Methods: The clinical role of 6mA was investigated by immunohistochemical (IHC) staining and Kaplan-Meier analysis of BC and their normal tissues. 6mA immunoprecipitation (IP) sequencing, mRNA sequencing and bioinformatics analysis were used to screen and validate the direct targets of 6mA. Results: Decreases in N6AMT1 correlated with the extent of 6mA in BC tissues and predicted a worse overall survival of BC patients. Knockdown N6AMT1 markedly reduced 6mA in DNA and promoted the proliferation and migration of BC in vivo and in vitro, whereas overexpression of N6AMT1 had the opposite effect, indicating N6AMT1 is a functional methyltransferase for DNA 6mA and relates with gene transcription. Critical negative regulators of the cell cycle, such as RB1, P21, REST and TP53 were identified as targets of N6AMT1 in BC. Conclusion: These results suggest N6AMT1 enhances DNA 6mA levels to repress tumor progression via transcriptional regulation of cell cycle inhibitors.

Project description:Small RNA sequencing was used to examine RNA degradation products in mitochondria from mice lacking the nuclease subunit of the mitochondrial RNase P (MRPP3).

Project description:Fatty acid synthesis is closely linked to nutrient availability and cellular energetic status. The committed step in fatty acid synthesis is the acetyl CoA carboxylase. Eukaryotes have two genes encoding acetyl CoA carboxylases, one encoding a cytosolic enzyme and another coding for a mitochondrial enzyme. They catalyze the synthesis of malonyl CoA in the cytosol and the mitochondria, respectively. While cytosolic malonyl CoA is the precursor for fatty acid synthesis, mitochondrial malonyl CoA controls the transfer of fatty acyl group into the mitochondria by inhibiting carnitine/palmitoyl transferase activity and thus, regulates β-oxidation. In Saccharomyces cerevisiae, β-oxidation is restricted to the peroxisomes, raising the question of the function of the mitochondrial isoform (HFA1). In this study, we replaced the cytosolic Acc1 with Hfa1 expressed in the cytosol by removing the mitochondrial leader peptide, under control of the HFA1 promoter. We studied fatty acid synthesis and transcription profiles in this strain during starvation for carbon or nitrogen, using glucose or ethanol as the carbon source. Under all the conditions studied, the key sensor of energetic status, Snf1, was activated, indicating active inhibition of fatty acid synthesis. The pool size of fatty acids was smaller when Acc1 was replaced with truncated Hfa1 for fatty acid synthesis. Yet, the transcription profiles were similar in both the cases. These results point towards the conclusion that Hfa1 is either catalytically less efficient or it is more sensitive to inhibition by Snf1. Gene expression from a strain of Saccharomyces cerevisiae where cytosolic fatty acid synthesis occurs by mitochondrial acetyl CoA carboxylase (without its mitochondrial leader peptide) is compared with that in a reference strain while growing in chemostats on carbon or nitrogen starvation using glucose or ethanol as the carbon source. There are two strains (reference or mutant), two carbon sources (glucose or ethanol) and two limitations (carbon or nitrogen), resulting in 8 comparisons. Each array was performed in duplicate, resulting in 16 CEL files. Growth was limited by either carbon or nitrogen. When carbon was the limited nutrient, we tested growth on either glucose or ethanol (both using ammonium sulfate as the nitrogen source). When ammonium sulfate was limiting, we used either glucose or ethanol as the carbon source.

Project description:In animals the organization of the compact mitochondrial genome and lack of introns have necessitated a unique mechanism for RNA processing. To date the regulation of mitochondrial RNA processing and its importance for ribosome biogenesis and energy metabolism are not clear. To understand the in vivo role of the endoribonuclease component of the RNase P complex, MRPP3, we created conditional knockout mice. Here we show that MRPP3 is essential for life, and heart and skeletal muscle-specific knockout leads to a cardiomyopathy early in life, indicating that it is the only RNase P enzyme in mitochondria. We show that RNA processing is required for the biogenesis of the respiratory chain and mitochondrial function. Transcriptome-wide parallel analyses of RNA ends (PARE) and RNA-Seq enabled us to identify the in vivo cleavage sites of RNase P. Cleavage of the 5′ tRNA ends precedes 3′ end processing in vivo and is required for the correct biogenesis of the mitochondrial ribosomal subunits and mitoribosomal proteins that are differentially stabilized or degraded in the absence of mature rRNAs. Finally we identify that large mitoribosomal proteins can form a subcomplex on a precursor mt-RNA containing the 16S rRNA indicating that mitoribosomal biogenesis proceeds co-transcriptionally. Taken together our data show that RNA processing links transcription to translation via assembly of the mitoribosome.