ABSTRACT
Various specialized domains have been described in the cytosol and the nucleus; however, little is known about compartmentalization within the mitochondrial matrix. GRSF1 (G-rich sequence factor 1) is an RNA binding protein that was previously reported to localize in the cytosol. We found that an isoform of GRSF1 accumulates in discrete foci in the mitochondrial matrix. These foci are composed of nascent mitochondrial RNA and also contain RNase P, an enzyme that participates in mitochondrial RNA processing. GRSF1 was found to interact with RNase P and to be required for processing of both classical and tRNA-less RNA precursors. In its absence, cleavage of primary RNA transcripts is abnormal, leading to decreased expression of mitochondrially encoded proteins and mitochondrial dysfunction. Our findings suggest that the foci containing GRSF1 and RNase P correspond to sites where primary RNA transcripts converge to be processed. We have termed these large ribonucleoprotein structures "mitochondrial RNA granules."
Subject(s)
Gene Expression Regulation/physiology , Mitochondria/metabolism , Poly(A)-Binding Proteins/metabolism , RNA Processing, Post-Transcriptional/physiology , RNA/metabolism , Ribonucleoproteins/metabolism , Blotting, Northern , Bromodeoxyuridine , Gene Expression Regulation/genetics , HEK293 Cells , Humans , Immunoprecipitation , Microscopy, Fluorescence , Protein Isoforms/metabolism , RNA Interference , RNA, Mitochondrial , Ribonuclease P/metabolismABSTRACT
In recent years there has been considerable and growing interest in the 3-dimensional organization of genomes. In this manuscript we present an integrated computational-molecular study that produces an ensemble of high-resolution 3-dimensional conformations of the budding yeast genome. The compaction, folding and spatial organization of the chromosomes was based on empirical data determined using proximity-based ligation. Our models incorporate external constraints that allow the separation of gross organizational effects from those due to local interactions. Our models show that yeast chromosomes have preferred yet non-exclusive positions. They also identify interaction dependent clustering of tRNAs, early firing origins of replication, and Gal4 protein binding sites, yet the cluster composition is dynamic. Our results support a link between structure and transcription that occurs within the context of a flexible genome organization.
Subject(s)
Chromosome Positioning , Chromosomes, Fungal/genetics , Chromosomes, Fungal/metabolism , Genetic Loci/genetics , Genome, Fungal/genetics , Saccharomyces cerevisiae/genetics , Schizosaccharomyces/genetics , Algorithms , Chromosomal Position Effects , Genes, Fungal/genetics , Models, Molecular , Molecular Dynamics Simulation , Nucleic Acid Conformation , RNA, Transfer/genetics , Saccharomyces cerevisiae/cytology , Schizosaccharomyces/cytologyABSTRACT
Nuclear and mitochondrial organelles must maintain a communication system. Loci on the mitochondrial genome were recently reported to interact with nuclear loci. To determine whether this is part of a DNA based communication system we used genome conformation capture to map the global network of DNA-DNA interactions between the mitochondrial and nuclear genomes (Mito-nDNA) in Saccharomyces cerevisiae cells grown under three different metabolic conditions. The interactions that form between mitochondrial and nuclear loci are dependent on the metabolic state of the yeast. Moreover, the frequency of specific mitochondrial-nuclear interactions (i.e. COX1-MSY1 and Q0182-RSM7) showed significant reductions in the absence of mitochondrial encoded reverse transcriptase machinery. Furthermore, these reductions correlated with increases in the transcript levels of the nuclear loci (MSY1 and RSM7). We propose that these interactions represent an inter-organelle DNA mediated communication system and that reverse transcription of mitochondrial RNA plays a role in this process.
Subject(s)
Cell Nucleus/genetics , DNA, Mitochondrial/genetics , Organelles/metabolism , Organelles/physiology , RNA, Messenger/genetics , Transcription, Genetic , Biological Transport/drug effects , Biological Transport/genetics , Biological Transport/physiology , Cell Nucleus/drug effects , Chromosomes, Fungal/drug effects , Chromosomes, Fungal/genetics , Chromosomes, Fungal/metabolism , Cyclooxygenase 1/genetics , Cyclooxygenase 1/metabolism , DNA, Mitochondrial/drug effects , DNA-Binding Proteins/genetics , DNA-Binding Proteins/metabolism , Epistasis, Genetic/drug effects , Epistasis, Genetic/physiology , Galactose/pharmacology , Gene Expression Regulation, Fungal/drug effects , Genetic Loci/physiology , Glucose/pharmacology , Organelles/drug effects , Organelles/genetics , RNA, Fungal/drug effects , RNA, Fungal/genetics , RNA, Fungal/metabolism , RNA, Messenger/metabolism , Saccharomyces cerevisiae/genetics , Saccharomyces cerevisiae/metabolism , Saccharomyces cerevisiae/physiology , Saccharomyces cerevisiae/ultrastructure , Time Factors , Transcription, Genetic/drug effectsABSTRACT
The three-dimensional organization of genomes is dynamic and plays a critical role in the regulation of cellular development and phenotypes. Here we use proximity-based ligation methods (i.e. chromosome conformation capture [3C] and circularized chromosome confrmation capture [4C]) to explore the spatial organization of tRNA genes and their locus-specific interactions with the ribosomal DNA. Directed replacement of one lysine and two leucine tRNA loci shows that tRNA spatial organization depends on both tRNA coding sequence identity and the surrounding chromosomal loci. These observations support a model whereby the three-dimensional, spatial organization of tRNA loci within the nucleus utilizes tRNA gene-specific signals to affect local interactions, though broader organization of chromosomal regions are determined by factors outside the tRNA genes themselves.
