Project description:Modern omics technologies allow us obtaining global information on different types of biological networks. However, integrating these different types of analyzes into a coherent framework for a comprehensive biological interpretation remains challenging. Here, we present a conceptual framework that integrates protein interaction, phosphoproteomics and transcriptomics data. Applying this method to analyze HRAS signaling from different subcellular compartments shows that spatially-defined networks contribute specific functions to HRAS signaling. Changes in HRAS protein interactions at different sites lead to different kinase activation patterns that differentially regulate gene transcription. HRAS mediated signaling is the strongest from the plasma membrane, but it regulates the largest number of genes from the endoplasmic reticulum. The integrated networks provide a topologically and functionally resolved view of HRAS signaling. They reveal new HRAS functions including the control of cell migration from the endoplasmic reticulum and p53 dependent cell survival when signaling from the Golgi apparatus.

Project description:Recent breakthroughs in single-cell genomics allow probing molecular states of cells with unprecedented detail along the sequence of the DNA. Biological function relies, however, on emergent processes in the three-dimensional space of the nucleus, such as droplet formation through phase separation. Here, we use single-cell multi-omics sequencing to develop a theoretical framework to rigorously map epigenome profiling along the DNA sequence onto a description of the emergent spatial dynamics in the nucleus. Drawing on scNMT-seq multi-omics sequencing in vitro and in vivo we exemplify our approach in the context of exit from pluripotency and global de novo methylation of the genome. We show how DNA methylation patterns of the embryonic genome are established through the interplay between spatially correlated DNA methylation and topological changes to the DNA. This feedback leads to the predicted formation of 30-40nm sized condensates of methylated DNA and determines genome-scale DNA methylation rates. We verify these findings with orthogonal single cell multi-omics data that combine the methylome with HiC measurements. Notably, this scale of chromatin organization has recently been described by super-resolution microscopy. Using this framework, we identify local methylation correlations in gene bodies that precede transcriptional changes at the exit from pluripotency. Our work provides a general framework of how mechanistic insights into emergent processes underlying cell fate decisions can be gained by the combination of single-cell multi-omics and methods from theoretical physics that have not been applied in the context of genomics before.

Project description:Recent breakthroughs in single-cell genomics allow probing molecular states of cells with unprecedented detail along the sequence of the DNA. Biological function relies, however, on emergent processes in the three-dimensional space of the nucleus, such as droplet formation through phase separation. Here, we use single-cell multi-omics sequencing to develop a theoretical framework to rigorously map epigenome profiling along the DNA sequence onto a description of the emergent spatial dynamics in the nucleus. Drawing on scNMT-seq multi-omics sequencing in vitro and in vivo we exemplify our approach in the context of exit from pluripotency and global de novo methylation of the genome. We show how DNA methylation patterns of the embryonic genome are established through the interplay between spatially correlated DNA methylation and topological changes to the DNA. This feedback leads to the predicted formation of 30-40nm sized condensates of methylated DNA and determines genome-scale DNA methylation rates. We verify these findings with orthogonal single cell multi-omics data that combine the methylome with HiC measurements. Notably, this scale of chromatin organization has recently been described by super-resolution microscopy. Using this framework, we identify local methylation correlations in gene bodies that precede transcriptional changes at the exit from pluripotency. Our work provides a general framework of how mechanistic insights into emergent processes underlying cell fate decisions can be gained by the combination of single-cell multi-omics and methods from theoretical physics that have not been applied in the context of genomics before.

Project description:To further our understanding of how biochemical information flows through cells upon external stimulation, we require single-cell multi-omics methods that concurrently map changes in (phospho)protein levels across signaling networks and the associated gene expression profiles. Here, we present Quantification of RNA and Intracellular Epitopes by sequencing (QuRIE-seq), a droplet-based platform for single-cell RNA and intra- and extracellular (phospho)protein quantification through sequencing. We applied QuRIE-seq to quantify cell-state changes of 6976 cells, at both the signaling and transcriptome level following 2, 4, 6, 60, and 180-minute stimulation of the B-cell receptor pathway (BCR) in Burkitt lymphoma cells (BJABs). Using the recently developed multi-factor omics analysis (MOFA+) framework we delineated changes in single-cell (phospho)protein and gene expression patterns over multiple timescales and revealed the effect of an inhibitory drug (Ibrutinib) on signaling and gene expression landscape.

Project description:Prednisone is anti-inflammatory glucocorticoid (GC), and GC-based therapy is most used combination chemotherapy for treating aggressive B-cell lymphomas. However, there are still gaps in our understanding of specific mechanism of GC’s action for its cytotoxicity. By performing multi-omics approaches, we identified new GR targets and how these targets control the b-cell receptor signaling networks, providing a mechanistic framework upon which to base combination therapies.

Project description:Modern omics technologies allow us obtaining global information on different types of biological networks. However, integrating these different types of analyzes into a coherent framework for a comprehensive biological interpretation remains challenging. Here, we present a conceptual framework that integrates protein interaction, phosphoproteomics and transcriptomics data. Applying this method to analyze HRAS signaling from different subcellular compartments shows that spatially-defined networks contribute specific functions to HRAS signaling. Changes in HRAS protein interactions at different sites lead to different kinase activation patterns that differentially regulate gene transcription. HRAS mediated signaling is the strongest from the plasma membrane, but it regulates the largest number of genes from the endoplasmic reticulum. The integrated networks provide a topologically and functionally resolved view of HRAS signaling. They reveal new HRAS functions including the control of cell migration from the endoplasmic reticulum and p53 dependent cell survival when signaling from the Golgi apparatus.

Project description:Modern omics technologies allow us obtaining global information on different types of biological networks. However, integrating these different types of analyzes into a coherent framework for a comprehensive biological interpretation remains challenging. Here, we present a conceptual framework that integrates protein interaction, phosphoproteomics and transcriptomics data. Applying this method to analyze HRAS signaling from different subcellular compartments shows that spatially-defined networks contribute specific functions to HRAS signaling. Changes in HRAS protein interactions at different sites lead to different kinase activation patterns that differentially regulate gene transcription. HRAS mediated signaling is the strongest from the plasma membrane, but it regulates the largest number of genes from the endoplasmic reticulum. The integrated networks provide a topologically and functionally resolved view of HRAS signaling. They reveal new HRAS functions including the control of cell migration from the endoplasmic reticulum and p53 dependent cell survival when signaling from the Golgi apparatus.

Project description:Although many methods have been developed for inference of biological networks, the validation of the resulting models has largely remained an unsolved problem. Here we present a framework for quantitative assessment of inferred gene interaction networks using knock-down data from cell line experiments. Using this framework we are able to show that network inference based on integration of prior knowledge derived from the biomedical literature with genomic data significantly improves the quality of inferred networks relative to other approaches. Our results also suggest that cell line experiments can be used to quantitatively assess the quality of networks inferred from tumor samples. Knock-down of eight genes were performed on colorectal cancer cell lines to identify the genes whose expression was significantly affected. These genes were subsequently used to validate the quality of our causal gene interaction network.

Project description:Rare cells exert substantial impact on tissue physiology and pathology across a spectrum of biological realms. The elucidation of their physiological functions through multi-omics analysis is pivotal. Nonetheless, advancements in trace-level cell multi-omics technology are impeded by cellular loss during experimental procedures. Mitochondrial DNA (mtDNA) editing facilitates disease modeling of mitochondrial genetic disorders in cell lines and animals, with potential for future therapeutic applications. However, the absence of technology capable of simultaneously assessing the efficiency of mitochondrial gene editors and molecular phenotypes limits the development of mitochondrial gene editors and their in vivo therapeutic applications. Here, to address these challenges, we devised a novel omics carrier microparticle, abbreviated as OmicsCam for driving low-input cells multi-omics. OmicsCam consists of three key components: miniaturized open microparticles for multi-step biochemistry, an enlarged cell chamber boundary for streamline manipulation and minimize cell loss, and tunable permeability to ensure compatibility with key steps of magnetic separation in automated systems. By refining OmicsCam's manufacturing process, optimizing cell permeation conditions, and fine-tuning multi-omics library biochemistry, we demonstrated simultaneous assessment of mtDNA editing efficiency (mtDNA sequencing), post-editing cellular transcriptome, and chromatin accessibility in minute cell samples containing as few as 25,000 cells. Moreover, we can concurrently analyze off-target effects of gene editing. The OmicsCam platform offers a powerful way for microscale cell multi-omics analysis, enabling interrogation mitochondrial gene editing efficiency and molecular phenotypes in a unified framework. This offers a holistic perspective on the consequences of genetic manipulation within the mitochondrial genome, thereby advancing our understanding of mitochondrial biology and facilitating the development of precision therapeutics for mitochondrial disorders.

Project description:Spatial profiling of proteins and protein interactions with mRNAs is essential for studies understanding cellular signaling. However, technologies capable of integrating these modalities remain limited. Here, we present Spatial Proximity-Sequencing (Sprox-seq), a method that combines proximity ligation assay with spatial transcriptomics to simultaneously profile mRNAs, surface proteins, and their interactions in intact tissues. Applied to human tonsil tissue, Sprox-seq profiled 32 proteins and their pairwise interactions alongside thousands of mRNAs. We developed a robust computational framework for analyzing protein proximity data, enabling both the statistical identification and interaction strength measurements of protein complexes. Clustering based on protein interaction strength recapitulated RNA-defined tissue architecture. Interaction networks constructed from protein complexes revealed significantly higher interaction complexity in Light zone. Trajectory inference based on protein interaction strength uncovered a maturation path distinct from that inferred by RNA data, and spatially enriched protein complexes were associated with functional gene-expression pathways. Moreover, Sprox-seq also captured cell–cell interactions mediated by protein complex ITGA4–VCAM1 in Light zone. Overall, Sprox-seq provides a spatially resolved, multi-modal view of cell states, offering a powerful tool for studying immune responses, tissue development, and disease progression.