Project description:Mitochondrial associated RNA-binding proteins (RBPs) have emerged as key contributors to mitochondrial biogenesis and homeostasis. With few examples described, we set out to identify RBPs that post-transcriptionally regulate nuclear-encoded mitochondrial mRNAs (NEMmRNAs). Our analysis of RNA-target sets of RBPs made available by ENCODE identified several RBPs with a preference for binding NEMmRNAs, of which we selected LARP4, a La RBP family member, for further study. We show that LARP4’s RNA-target set is particularly enriched in mRNAs that encode for respiratory chain complex proteins (RCCPs) and mitochondrial ribosome proteins (MRPs) across multiple human cell lines. CRISPR knockout cells in conjunction with quantitative proteomics show that protein levels of RCCPs and MRPs are significantly reduced upon loss of LARP4. Furthermore, we show that LARP4 depletion reduces mitochondrial function, and this phenotype is ameliorated by LARP4 re-expression. Our findings shed light onto a novel function for LARP4 as an RBP that binds to NEMmRNAs to promote mitochondrial respiratory function.

Project description:Mitochondria-associated RNA-binding proteins have emerged as key contributors to mitochondrial biogenesis and homeostasis. With few examples known, we set out to identify RBPs that regulate nuclear-encoded mitochondrial mRNAs. Our systematic analysis of RNA targets of 150 RBPs identified RBPs with a preference for binding NEM mRNAs, including LARP4, a La RBP family member. We show that LARP4s targets are particularly enriched in mRNAs that encode respiratory chain complex proteins and mitochondrial ribosome proteins across multiple human cell lines. Through quantitative proteomics, we demonstrate that depletion of LARP4 leads to a significant reduction in RCCP and MRP protein levels. Furthermore, we show that LARP4 depletion reduces mitochondrial function, and that LARP4 re-expression rescues this phenotype. Our findings shed light on a novel function for LARP4 as an RBP that binds to and positively regulates NEM mRNAs to promote mitochondrial respiratory function.

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Project description:Current evidence suggests that nuclear-encoded mitochondrial proteins can be locally translated at the mitochondrial surface and co-translationally or post-translationally imported into mitochondria. mRNA localization on the mitochondrial membrane, a prerequisite for localized translation, remains uncharacterized in higher eukaryotic organisms. We employed fractionation-sequencing to profile mitochondria-associated mRNAs in zebrafish larvae. Our transcriptome-wide analysis reveals the localization of mRNAs of only 12% of the nuclear-encoded mitochondrial proteins to the mitochondrial surface, which suggests that post-translational import is the dominant mode of protein import to mitochondria. Additionally, the mRNAs which were localized to the mitochondrial membrane consisted mostly of those encoding proteins involved in mitochondrial dynamics, suggesting their site-specific translation. Finally, we show that the loss of function of the MIA pathway responsible for the post-translational import of a subclass of mitochondrial proteins, triggers mitochondrial localization of mRNAs encoding proteins that are imported to mitochondria via other pathways. Thus, our study suggests that mRNA targeting and localized translation could be relevant in higher eukaryotes to combat stress conditions affecting mitochondrial biogenesis in general. 

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Project description:To identify and analyze mtDNA mutation-responsive genes, a comparison of gastrocnemius muscle tissues from WT (control) and D257A mice was conducted. We examined changes in gene expression in the muscle associated with mtDNA mutations. 1) Types of experiments: a) Effect of mitochondrial DNA (mtDNA) mutations b) Effect of aging c) WT (13 month-old Polg+/+ mice) vs. D257A (13 month-old PolgD257A/D257A) mice 2) Experimental factors: a) Type of gene: PolgD257A/D257A b) Time (age) 3) Number of hybridizations in the study: ~10 4) A common reference RNA was not used. 5) Quality control measures were not used. No replicates were done. Dye swap was not used.

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