Project description:Asymmetric mRNA localization facilitates efficient translation in cells such as neurons and fibroblasts. However, the extent and significance of mRNA polarization in epithelial tissues is unclear. Here, we used single molecule transcript imaging and subcellular transcriptomics to uncover global apical-basal intracellular polarization of mRNA in the mouse intestinal epithelium. The localization of mRNAs did not generally overlap protein localization. Instead, ribosomes were more abundant on the apical sides, and apical transcripts were consequently more efficiently translated. Refeeding of fasted mice elicited a basal to apical shift in polarization of mRNAs encoding ribosomal proteins, which was associated with a specific boost in their translation. This lead to increased protein production, required for efficient nutrient absorption. These findings reveal a post-transcriptional regulatory mechanism involving dynamic polarization of mRNA and polarized translation.

Project description:Asymmetric mRNA localization facilitates efficient translation in cells such as neurons and fibroblasts. However, the extent and significance of mRNA polarization in epithelial tissues is unclear. Here, we used single molecule transcript imaging and subcellular transcriptomics to uncover global apical-basal intracellular polarization of mRNA in the mouse intestinal epithelium. The localization of mRNAs did not generally overlap protein localization. Instead, ribosomes were more abundant on the apical sides, and apical transcripts were consequently more efficiently translated. Refeeding of fasted mice elicited a basal to apical shift in polarization of mRNAs encoding ribosomal proteins, which was associated with a specific boost in their translation. This lead to increased protein production, required for efficient nutrient absorption. These findings reveal a post-transcriptional regulatory mechanism involving dynamic polarization of mRNA and polarized translation.

Project description:Subcellular mRNA localization patterns across tissues resolved with spatial transcriptomics

Project description:Subcellular RNA localization is crucial for the spatio-temporal control of protein synthesis and underlies key processes during development, homeostasis and disease. In epithelial cells, RNA can localize asymmetrically along the apico-basal axis. Yet, we ignore the localization of most transcripts as well as the diversity of patterns that they adopt. Here, we utilized proximity labeling (APEX-seq) and spatial transcriptomics (MERFISH) to map subcellular transcript localization in intestinal organoids and adult mice tissue. Many transcripts presented localization bias, often localizing in granular structures. We described the intrinsic and environmental factors that influence the formation of these patterns. We identified translation-dependent and -independent localization patterns and pintointed the role of 3’ UTRs and RNA-binding proteins. This subcellular RNA atlas can be referenced to extract new biological insights and provide hypothesis-free observation on spatial transcriptomics.

Project description:RNA subcellular localization often correlates with its function and regulation. For many long noncoding RNAs (lncRNAs) and some isoforms of coding genes, their transcripts are preferentially retained on the chromatin. However, the mechanisms controlling the chromatin retention of lncRNAs and mRNA transcripts remain largely unknown. We hypothesize that embedded RNA sequences and interacting proteins may be the cis and trans regulators governing RNA subcellular localization, respectively. To comprehensively identify the cis-regulatory elements of RNA transcript, here we have developed a high-throughput sequencing-based method named RNA elements for subcellular localization by sequencing (REL-seq). Using this method, we identified RNA sequences contribute to the chromatin retention of several transcripts. By combining REL-seq with random mutagenesis (mutREL-seq), we further narrowed down the key RNA motifs and residues in regulating their subcellular localization at base resolution. Finally, based on the RNA element we identified, we revealed and confirmed U1 snRNA targeting site contributes to RNA chromatin retention.

Project description:Cystic Fibrosis (CF) is a genetic disorder CF is caused by mutations of the gene encoding for the cystic fibrosis transmembrane conductance regulator protein (CFTR), a transmembrane anion channel expressed at the apical membrane of several organs, including the epithelial cells of the airway. CFTR mutations result in dysfunctional ion transport across the apical membrane at the surface of the epithelia, generating thickened and dehydrated secretions. In the lung, this leads to a decrease in the mucociliary clearance, favoring bacterial colonization and progressive obstruction of the duct. Although over 2000 CFTR variants have been identified so far, the most common mutation is a deletion of the phenylalanine in position 508 (F508del), which shows an allelic frequency of around 90% among CF patients. F508del-CFTR is incorrectly folded, causing its retention at the endoplasmic reticulum (ER) and subsequent proteasomal degradation. Among the several drugs available in CF pharmacological treatment, VX-809 (commercial name Lumacaftor) is the most used drug for patients carrying F508del-CFTR mutation. This drug corrects the aberrant folding of F508del-CFTR by favoring the correct intramolecular interactions, thus enabling a higher number of copies of the defective protein to reach the plasma membrane. Localization of Organelle Proteins by Isotope Tagging after Differential ultra-Centrifugation (LOPIT-DC, https://doi.org/10.1038/s41467-018-08191-w) workflow was used to study the spatial localization of proteins in the CFBE41o- cells and how it is impacted by CFTR rescue triggered by VX-809. LOPIT-DC is a powerful and well-established tool for the investigation of the spatial distribution of global proteome within cells, which combines subcellular fractionation based on differential centrifugation, quantitative mass spectrometry, and machine learning. Its application provides a global snapshot of the steady-state subcelluler distribution of proteins. The aim of this project is to identify proteins that change their cellular localization in association with the treatment, to uncover molecules that play a role in the trafficking of the defective CFTR to the plasma membrane.

Project description:The transport of mRNAs to distal subcellular compartments is an important component of spatial gene expression control in neurons. However, the mechanisms that control mRNA localization in neurons are not completely understood. Here, we identify the abundant base modification, m6A, as a regulator of mRNA localization in neurons. Transcriptome-wide analysis of mRNA localization in neurons following genetic loss of m6A reveals hundreds of transcripts that exhibit altered subcellular localization. Additionally, using a reporter system, we show that mutation of specific m6A sites in select neuronal transcripts diminishes their localization to neurites. Single molecule fluorescent in situ hybridization experiments further confirm our findings and identify the m6A reader proteins YTHDF2 and YTHDF3 as mediators of this effect. Our findings reveal a novel function for m6A in controlling mRNA localization in neurons and enable a better understanding of the mechanisms through which m6A influences gene expression in the brain.

Project description:Subcellular Level Spatial Transcriptomics with PHOTON

Project description:Recent breakthroughs in spatial transcriptomics technologies have enhanced our understanding of diverse cellular identities, spatial organizations, and functions. Yet existing spatial transcriptomics tools are still limited in either transcriptomic coverage or spatial resolution, hindering unbiased, hypothesis-free transcriptomic analyses at high spatial resolution. Here we develop Reverse-padlock Amplicon Encoding FISH (RAEFISH), an image-based spatial transcriptomics method with whole-genome coverage and single-molecule resolution in intact tissues. We demonstrate spatial profiling of 23,000 human or 22,000 mouse transcripts in single cells and tissue sections. Our analyses reveal transcript-specific subcellular localization, cell-type-specific and cell-type-invariant zonation-dependent transcriptomes, and gene programs underlying preferential cell-cell interactions. Finally, we further develop our technology for direct spatial readout of gRNAs in an image-based high-content CRISPR screen. Overall, these developments provide the research community with a broadly applicable technology that enables high-coverage, high-resolution spatial profiling of both long and short, native and engineered RNA species in many biomedical contexts.

Project description:The transport of mRNAs to distal subcellular compartments is an important component of spatial gene expression control in neurons. However, the mechanisms that control mRNA localization in neurons are not completely understood. Here, we identify the abundant base modification, m6A, as a novel regulator of this process. Transcriptome-wide analysis following genetic loss of m6A reveals hundreds of transcripts that exhibit altered subcellular localization in hippocampal neurons. Additionally, using a reporter system, we show that mutation of specific m6A sites in select neuronal transcripts diminishes their localization to neurites. Single molecule fluorescent in situ hybridization experiments further confirm our findings and identify the m6A reader proteins YTHDF2 and YTHDF3 as mediators of this effect. Our findings reveal a novel function for m6A in controlling mRNA localization in neurons and enable a better understanding of the mechanisms through which m6A influences gene expression in the brain.