Project description:Deep-Red and Ultrafast Photocatalytic Proximity Labeling Empowered in situ Dissection of Tumor-Immune Interactions in Primary Tissues

Project description:In situ profiling of subcellular proteomic networks in primary and living systems, such as primary cells from native tissues or clinic samples, is crucial for the understanding of life processes and diseases, yet challenging for the current proximity labeling methods (e.g., BioID, APEX) due to their necessity of genetic engineering. Here we report CAT-S, a state-of-the-art bioorthogonal photocatalytic chemistry-enabled proximity labeling method, that expands proximity labeling to a wide range of primary living samples for in situ profiling of subcellular proteomes. Powered by the newly introduced thioQM labeling warhead and targeted bioorthogonal photocatalytic decaging chemistry, CAT-S enables labeling of mitochondrial proteins in living cells with high efficiency and specificity (up to 87%). We applied CAT-S to diverse cell cultures, mouse tissues as well as primary T cells from human blood, portraying the native-state mitochondrial proteomic characteristics, and unveiled a set of hidden mitochondrial proteins in human proteome. Furthermore, CAT-S allows quantitative analysis of the in situ proteomic perturbations on dysfunctional tissue samples, exampled by diabetic mouse kidneys, and revealed the alterations of lipid metabolism machinery that drive the disease progression. Given the advantages of non-genetic operation, generality, efficiency as well as spatiotemporal resolution, CAT-S may open new avenues as a proximity labeling strategy for in situ investigation of subcellular proteomic landscape of primary living samples that are otherwise inaccessible.

Project description:Off-the-shelf proximity labeling

Project description:This proof-of-principle experiment was designed to demonstrate the feasibility of proximity labeling for RNA–protein interactions

Project description:Cell–cell interactions (CCIs) are essential for tissue functionality and targeted therapies, particularly in the context of chimeric antigen receptor T (CAR T) cells. Here, we introduce TyP-HIM-seq, a barcoding approach based on tyrosinase-catalyzed proximity (TyP) labeling. This method enables the simultaneous high-throughput measurement of interacting cells and their mRNA expressions through single-cell sequencing. By translating intercellular contact into in situ chemical labeling of a DNA barcode, TyP-HIM-seq allows for a comprehensive assessment of CCIs and full deconvolution of related molecular pathways. We used TyP-HIM-seq to investigate the CCIs between CD19 CAR-Jurkat cells and Ramos tumor cells.

Project description:Remote enhancers are thought to interact with their target promoters via physical proximity, yet the importance of this proximity for enhancer function remains unclear. Here, we investigate the 3D conformation of enhancers during mammalian development by generating high-resolution tissue-resolved contact maps for nearly a thousand enhancers with characterized in vivo activities in ten murine embryonic tissues. 61% of developmental enhancers bypass their neighboring genes, which are often marked by promoter CpG methylation. The majority of enhancers display tissue-specific 3D conformations, and both enhancer–promoter and enhancer–enhancer interactions are moderately but consistently increased upon enhancer activation in vivo. Less than 14% of enhancer–promoter interactions form stably across tissues; however, these invariant interactions form in the absence of the enhancer and are likely mediated by adjacent CTCF binding. Our results highlight the general significance of enhancer–promoter physical proximity for developmental gene activation in mammals.

Project description:Spatial proteomics enables in-depth mapping of cellular components and tissue architectures, mostly achieved by laser microdissection-mass spectrometry (LMD-MS) and antibody-based imaging. However, the trade-offs among sampling resolution, throughput, and proteome coverage still limit the applicability of these strategies, especially toward deep proteome profiling with high spatial resolution. Here, we propose PSPro (Proximity labeling for Spatial Proteomics) by leveraging precise antibody-targeted biotinylation at three-dimension scale and efficient affinity purification for MS-based cell-type-specific proteome profiling from single tissue slice. With fine-tuned labeling parameters, PSPro achieves all-at-once cell-type proteome capture with sub-micrometer resolution and shows comparable performance to flow cytometry- and LMD-based proteomic workflows. We apply PSPro to fixed tumor and spleen slices, enriching thousands of proteins containing known markers from ten cell types. For tissue microenvironments with high heterogeneity, we further incorporate region-resolved LMD into PSPro to facilitate direct comparison of cell subpopulations from the same tissue slice, revealing spatial proteome heterogeneity of cancer cells and immune cells in pancreatic tumor. Collectively, PSPro converts traditional “antibody-epitope” paradigm to “antibody-cell type proteome” for spatial biology in a user-friendly manner.

Project description:This proof-of-principle experiment was designed to demonstrate the feasibility of proximity labeling for RNAM-bM-^@M-^Sprotein interactions IPL-seq on 293T-Rex expressing MSA-SNRPN70 (sample) or NFH-SNRPN70 (control)

Project description:BAP-seq proximity labeling of subcellular compartments

Project description:Profiling stress-triggered RNA condensation with photocatalytic proximity labeling