Project description:Gastrulation is a critical stage of embryonic development during which the three germ layers are established. Deciphering the molecular mechanisms underlying this process from a protein perspective remains a significant challenge. To address this, we employed a multilayered mass spectrometry-based proteomics approach to investigate the global dynamics of (phospho)protein expression during differentiation of ESCs towards gastruloids – an in vitro model of gastrulation-stage embryogenesis. Our findings revealed that many proteins exhibited temporal expression during gastrulation with unique expression profiles corresponding to the three germ layers, which we also validated using an ultra sensitive single cell proteomics approachtechnology. Additionally, we profiled enhancer interaction landscapes in ESCs and gastruloids using p300 proximity labeling, which revealed numerous gastruloid-specific transcription factors and chromatin remodelers. Subsequent degron based perturbations combined with scRNA-seq revealed a critical role for Zeb2 in regulating mouse and human somitogenesis. Overall, this study provides a rich resource for developmental and synthetic biology communities endeavoring to understand mammalian embryogenesis.

Project description:The analysis of single cell proteomes has recently become a viable complement to transcript and genomics studies. Proteins are the main driver of cellular functionality and mRNA levels are often an unreliable proxy of such. Therefore, the global analysis of the proteome is essential to study cellular identities. Both multiplexed and label-free mass spectrometry-based approaches with single cell resolution have lately attributed surprising heterogeneity to believed homogenous cell populations. Even though specialized experimental designs and instrumentation have demonstrated remarkable advances, the efficient sample preparation of single cells still lacks behind. Here, we introduce the proteoCHIP, a universal option for single cell proteomics sample preparation at surprising sensitivity and throughput. The automated processing using a commercial system combining single cell isolation and picoliter dispensing, the cellenONE®, allows to reduce final sample volumes to low nanoliters submerged in a hexadecane layer simultaneously eliminating error prone manual sample handling and overcoming evaporation. With this specialized workflow we achieved around 1,000 protein groups per analytical run at remarkable reporter ion signal to noise while reducing or eliminating the carrier proteome. We identified close to 2,000 protein groups across 158 multiplexed single cells from two highly similar human cell types and clustered them based on their proteome. In-depth investigation of regulated proteins readily identified one of the main drivers for tumorigenicity in this cell type. Our workflow is compatible with all labeling reagents, can be easily adapted to custom workflows and is a viable option for label-free sample preparation. The specialized proteoCHIP design allows for the direct injection of label-free single cells via a standard autosampler resulting in the recovery of 30% more protein groups compared to samples transferred to PEG coated vials. We therefore are confident that our versatile, sensitive, and automated sample preparation workflow will be easily adoptable by non-specialized groups and will drive biological applications of single cell proteomics.

Project description:Recent developments in mass spectrometry-based single-cell proteomics (SCP) have resulted in dramatically improved sensitivity, yet the relatively low measurement throughput remains a limitation. Isobaric and isotopic labeling methods have been separately applied to SCP to increase throughput through multiplexing. Here we combined both forms of labeling to achieve multiplicative scaling for higher throughput. Two-plex stable isotope labeling of amino acids in cell culture and isobaric Tandem Mass Tag labeling enabled up to 32 single cells to be analyzed in a single LC-MS analysis, in addition to reference and negative control channels. A custom nested nanowell chip was used for nanoliter sample processing to minimize sample losses. Using a 145-min total LC-MS cycle time, ~280 single cells were analyzed per day, which could be increased to ~700 samples per day with a high-duty-cycle multicolumn LC system producing the same active gradient. The labeling efficiency and achievable proteome coverage were characterized for multiple analysis conditions. Despite some decrease in coverage, this method readily differentiated four different cell types and thus proves suitable for, e.g., rapid cell typing.

Project description:Spatial tissue proteomics integrating whole-slide imaging, laser microdissection and ultrasensitive mass spectrometry is a powerful approach to link cellular phenotypes to functional proteome states in (patho)physiology. To be applicable to large patient cohorts and low sample input amounts, including single-cell applications, loss-minimized and streamlined end-to-end workflows are key. We here introduce an automated sample preparation protocol for laser microdissected samples utilizing the cellenONE® robotic system, which has the capacity to process 192 samples in three hours. Following laser microdissection collection directly into the proteoCHIP LF 48 or EVO 96 chip, our optimized protocol facilitates lysis, formalin de-crosslinking and tryptic digest of low-input archival tissue samples. The seamless integration with the Evosep ONE LC system by centrifugation allows ‘on-the-fly’ sample clean-up, particularly pertinent for laser microdissected workflows. We validate our method in human tonsil archival tissue, where we profile proteomes of spatially-defined B-cell, T-cell and epithelial microregions of 4,000 µm2 to a depth of ~2,000 proteins and with high cell type specificity. We finally provide detailed equipment templates and experimental guidelines for broad accessibility.

Project description:Single-cell proteomics (SCP) promises to revolutionize biomedicine by providing an unparalleled view of the proteome in individual cells. Here, we present a high-sensitivity SCP workflow identifying >5000 proteins in individual HeLa cells. It also facilitated direct detection of post-translational modifications (PTMs) in single-cells, negating the need for specific PTM-enrichment. Our study demonstrates the feasibility of processing up to 80 label-free SCP samples per day. An optimized tissue dissociation buffer enabled effective single cell disaggregation of drug-treated cancer cell spheroids, refining overall SCP analysis. Analyzing non-directed induced pluripotent stem cell (iPSC) differentiation, we consistently quantified stem cell markers OCT4 and SOX2 in hiPSCs and lineage markers like GATA4 (mesoderm), HAND1 (endoderm) and MAP2 (ectoderm) in different embryoid body cells. Our workflow sets a new benchmark in SCP for sensitivity and throughput, with broad applications in basic biology and biomedicine for identification of cell type-specific markers and therapeutic targets.

Project description:Single-cell proteomics (SCP) promises to revolutionize biomedicine by providing an unparalleled view of the proteome in individual cells. Here, we present a high-sensitivity SCP workflow identifying >5000 proteins in individual HeLa cells. It also facilitated direct detection of post-translational modifications (PTMs) in single-cells, negating the need for specific PTM-enrichment. Our study demonstrates the feasibility of processing up to 80 label-free SCP samples per day. An optimized tissue dissociation buffer enabled effective single cell disaggregation of drug-treated cancer cell spheroids, refining overall SCP analysis. Analyzing non-directed induced pluripotent stem cell (iPSC) differentiation, we consistently quantified stem cell markers OCT4 and SOX2 in hiPSCs and lineage markers like GATA4 (mesoderm), HAND1 (endoderm) and MAP2 (ectoderm) in different embryoid body cells. Our workflow sets a new benchmark in SCP for sensitivity and throughput, with broad applications in basic biology and biomedicine for identification of cell type-specific markers and therapeutic targets.

Project description:Single-cell proteomics (SCP) promises to revolutionize biomedicine by providing an unparalleled view of the proteome in individual cells. Here, we present a high-sensitivity SCP workflow identifying >5000 proteins in individual HeLa cells. It also facilitated direct detection of post-translational modifications (PTMs) in single-cells, negating the need for specific PTM-enrichment. Our study demonstrates the feasibility of processing up to 80 label-free SCP samples per day. An optimized tissue dissociation buffer enabled effective single cell disaggregation of drug-treated cancer cell spheroids, refining overall SCP analysis. Analyzing non-directed induced pluripotent stem cell (iPSC) differentiation, we consistently quantified stem cell markers OCT4 and SOX2 in hiPSCs and lineage markers like GATA4 (mesoderm), HAND1 (endoderm) and MAP2 (ectoderm) in different embryoid body cells. Our workflow sets a new benchmark in SCP for sensitivity and throughput, with broad applications in basic biology and biomedicine for identification of cell type-specific markers and therapeutic targets.

Project description:Although single cell RNA-seq has had a tremendous impact on biological research, a corresponding technology for unbiased mass spectrometric analysis of single cells has only recently become available. Significant technological breakthroughs including miniaturized sample handling have enabled proteome profiling of single cells. Further, a trapped ion mobility spectrometry (TIMS) in combination with parallel accumulation-serial fragmentation operated with data-dependant acquisition mode has allowed improved proteome coverage from low-input samples. It has been demonstrated that modulating ion flux in TIMS affects overall performance of proteome profiling. However, the effect of TIMS settings for analyzing low-input samples has been less investigated. Thus, we sought to optimize conditions of TIMS in regards of ion accumulation/ramp times and ion mobility range for low-input samples. We observed that ion accumulation times of 180 ms and monitoring a narrower ion mobility range from 0.7 to 1.3 Vs cm-2 resulted in a substantial gain in the depth of proteome coverage and in detecting proteins with low abundance. We applied these optimized conditions for proteome profiling of sorted human primary T cells, which yielded an average of 365, 804, 1,116, and 1,651 proteins from single, five, ten, and forty T cells, respectively. Notably, we demonstrated that the depth of proteome coverage from low number of cells was sufficient to delineate several essential metabolic pathways and T cell receptor signaling pathway. Finally, we showed the feasibility of detecting post-translational modifications including phosphorylation and acetylation from single cells. We believe that these parameters could be applied to label-free analysis of single cells obtained from clinically relevant samples.

Project description:Using an optimized data-independent acquisition approach on trapped ion mobility spectrometry, we measured proteins, post-translational modifications and variant peptides in single cells and single nuclei, which provided insights into heterogeneity of cell-state and signaling dependencies at the single cell level and the molecular impact of an epigenetic drug at the level of a single organelle.

Project description:Gastrulation represents a pivotal point in mammalian development, when the basic body plan is established and cells are specified into one of the three germ layers. This is followed by rapid diversification into specific lineages and the appearance of the various cell types required to build each of the organs. The rich variety of cell types present at this stage has never been rigorously characterised in any mammalian organism, and thus insight into cell fate decisions and the underlying regulatory networks have been inaccessible. We have used droplet based single-cell RNA-sequencing to address this by profiling ~20000 cells from C57BL/6 E8.25 mouse embryos.