LARP4 is an RNA-binding protein that binds nuclear-encoded mitochondrial mRNAs to promote mitochondrial function

The role of mitochondrial mRNA translation in cellular communication

Mitochondria are dynamic and heterogeneous organelles that rewire their network and metabolic functions in response to changing cellular needs. To this end, mitochondria integrate a plethora of incoming signals to influence cell fate and survival. A crucial and highly regulated node of cell-mitochondria communication is the translation of nuclear-encoded mitochondrial mRNAs. By controlling and monitoring the spatio-temporal translation of these mRNAs, cells can rapidly adjust mitochondrial function to meet metabolic demands, optimise ATP production and regulate organelle biogenesis and turnover. In this Review, we focus on how RNA-binding proteins that recognise nuclear-encoded mitochondrial mRNAs acutely modulate the rate of translation in response to nutrient availability. We further discuss the relevance of localised translation of these mRNAs for subsets of mitochondria in polarised cells. Finally, we highlight quality control mechanisms that monitor the translation process at the mitochondrial surface and their connections to mitophagy and stress responses. We propose that these processes collectively contribute to mitochondrial specialisation and signalling function.

Cell surface RNA biology: new roles for RNA binding proteins

Much of our understanding of RNA-protein interactions, and how these interactions shape gene expression and cell state, have come from studies looking at these interactions in vitro or inside the cell. However, recent data demonstrates the presence of extracellular and cell surface-associated RNA such as glycosylated RNA (glycoRNA), suggesting an entirely new environment and cellular topology in which to study RNA-RNA binding protein (RBP) interactions. Here, we explore emerging ideas regarding the landscape of cell surface RNA and RBPs. We also discuss open questions concerning the trafficking and anchoring of RBPs to the cell surface, whether cell surface RBPs (csRBPs) directly interact with cell surface RNA, and how changes in the presentation of csRBPs may drive autoimmune responses.

The short conserved region-2 of LARP4 interacts with ribosome-associated RACK1 and promotes translation

LARP4 interacts with poly(A)-binding protein (PABP) to protect messenger RNAs (mRNAs) from deadenylation and decay, and recent data indicate it can direct the translation of functionally related mRNA subsets. LARP4 was known to bind RACK1, a ribosome-associated protein, although the specific regions involved and relevance had been undetermined. Here, through a combination of in-cell and in vitro methodologies, we identified positions 615-625 in conserved region-2 (CR2) of LARP4 (and 646-656 in LARP4B) as directly binding RACK1. Consistent with these results, AlphaFold2-Multimer predicted high-confidence interaction of CR2 with RACK1 propellers 5 and 6. CR2 mutations strongly decreased LARP4 association with cellular RACK1 and ribosomes by multiple assays, whereas PABP association was less affected, consistent with independent interactions. The CR2 mutations decreased LARP4's ability to stabilize a β-globin mRNA reporter containing an AU-rich element (ARE) to higher degree than β-globin and GFP (green fluorescent protein) mRNAs lacking the ARE. We show LARP4 robustly increases translation of β-glo-ARE mRNA, whereas the LARP4 CR2 mutant is impaired. Analysis of nanoLuc-ARE mRNA for production of luciferase activity confirmed LARP4 promotes translation efficiency, while CR2 mutations are disabling. Thus, LARP4 CR2-mediated interaction with RACK1 can promote translational efficiency of some mRNAs.

Insights into the regulation of mRNA translation by scaffolding proteins

Regionalisation of molecular mechanisms allows cells to fine-tune their responses to dynamic environments. In this context, scaffolds are well-known mediators of localised protein activity. These phenomenal proteins act as docking sites where pathway components are brought together to ensure efficient and reliable flow of information within the cell. Although scaffolds are mostly understood as hubs for signalling communication, some have also been studied as regulators of mRNA translation. Here, we provide a brief overview of the work unravelling how scaffolding proteins facilitate the cross-talk between the two processes. Firstly, we examine the activity of AKAP1 and AKAP12, two signalling proteins that not only have the capacity to anchor mRNAs to membranes but can also regulate protein synthesis. Next, we review the studies that uncovered how the ribosome-associated protein RACK1 orchestrates translation initiation. We also discuss the evidence pointing to the scaffolds Ezrin and LASP1 as regulators of early translation stages. In the end, we conclude with some open questions and propose future directions that will bring new insights into the regulation of mRNA translation by scaffolding proteins.

The short conserved region-2 of LARP4 interacts with ribosome-associated RACK1 and promotes translation

LARP4 interacts with poly(A)-binding protein (PABP) to protect mRNAs from deadenylation and decay, and recent data indicate it can direct the translation of functionally related mRNA subsets. LARP4 was known to bind RACK1, a ribosome-associated protein, although the specific regions involved, and relevance had been undetermined. Here, yeast two-hybrid domain mapping followed by other methods identified positions 615-625 in conserved region-2 (CR2) of LARP4 (and LARP4B) as directly binding RACK1 region 200-317. Consistent with these results, AlphaFold2-multimer predicted high confidence interaction of CR2 with RACK1 propellers 5-6. CR2 mutations strongly decreased LARP4 association with cellular RACK1 and ribosomes by multiple assays, whereas less effect was observed for PABP association, consistent with independent interactions. CR2 mutations decreased LARP4 ability to optimally stabilize a β-globin mRNA reporter containing an AU-rich element (ARE) more significantly than a β-globin and other reporters lacking this element. While polysome profiles indicate the β-glo-ARE mRNA is inefficiently translated, consistent with published data, we show that LARP4 increases its translation whereas the LARP4-CR2 mutant is impaired. Analysis of nanoLuc-ARE mRNA for production of luciferase activity confirmed LARP4 promotes translation efficiency while CR2 mutations are disabling. Thus, LARP4 CR2-mediated interaction with RACK1 can promote translational efficiency of some mRNAs.

Human cells contain myriad excised linear intron RNAs with links to gene regulation and potential utility as biomarkers

A previous study using Thermostable Group II Intron Reverse Transcriptase sequencing (TGIRT-seq) found human plasma contains short (≤300 nt) structured full-length excised linear intron (FLEXI) RNAs with potential to serve as blood-based biomarkers. Here, TGIRT-seq identified >9,000 different FLEXI RNAs in human cell lines, including relatively abundant FLEXIs with cell-type-specific expression patterns. Analysis of public CLIP-seq datasets identified 126 RNA-binding proteins (RBPs) that have binding sites within the region corresponding to the FLEXI or overlapping FLEXI splice sites in pre-mRNAs, including 53 RBPs with binding sites for ≥30 different FLEXIs. These included splicing factors, transcription factors, a chromatin remodeling protein, cellular growth regulators, and proteins with cytoplasmic functions. Analysis of ENCODE datasets identified subsets of these RBPs whose knockdown impacted FLEXI host gene mRNA levels or proximate alternative splicing, indicating functional interactions. Hierarchical clustering identified six subsets of RBPs whose FLEXI binding sites were co-enriched in six subsets of functionally related host genes: AGO1-4 and DICER, including but not limited to agotrons or mirtron pre-miRNAs; DKC1, NOLC1, SMNDC1, and AATF (Apoptosis Antagonizing Transcription Factor), including but not limited to snoRNA-encoding FLEXIs; two subsets of alternative splicing factors; and two subsets that included RBPs with cytoplasmic functions (e.g., LARP4, PABPC4, METAP2, and ZNF622) together with regulatory proteins. Cell fractionation experiments showed cytoplasmic enrichment of FLEXI RNAs with binding sites for RBPs with cytoplasmic functions. The subsets of host genes encoding FLEXIs with binding sites for different subsets of RBPs were co-enriched with non-FLEXI other short and long introns with binding sites for the same RBPs, suggesting overarching mechanisms for coordinately regulating expression of functionally related genes. Our findings identify FLEXIs as a previously unrecognized large class of cellular RNAs and provide a comprehensive roadmap for further analyzing their biological functions and the relationship of their RBPs to cellular regulatory mechanisms.

The RNA binding proteins LARP4A and LARP4B promote sarcoma and carcinoma growth and metastasis

RNA-binding proteins (RBPs) are emerging as important regulators of cancer pathogenesis. We reveal that the RBPs LARP4A and LARP4B are differentially overexpressed in osteosarcoma and osteosarcoma lung metastases, as well as in prostate cancer. Depletion of LARP4A and LARP4B reduced tumor growth and metastatic spread in xenografts, as well as inhibiting cell proliferation, motility, and migration. Transcriptomic profiling and high-content multiparametric analyses unveiled a central role for LARP4B, but not LARP4A, in regulating cell cycle progression in osteosarcoma and prostate cancer cells, potentially through modulating key cell cycle proteins such as Cyclins B1 and E2, Aurora B, and E2F1. This first systematic comparison between LARP4A and LARP4B assigns new pro-tumorigenic functions to LARP4A and LARP4B in bone and prostate cancer, highlighting their similarities while also indicating distinct functional differences. Uncovering clear biological roles for these paralogous proteins provides new avenues for identifying tissue-specific targets and potential druggable intervention.