Project description:Protein misfolding diseases, including alpha-1 antitrypsin deficiency (AATD), pose significant health challenges, yet their progression at the cellular level remains poorly understood. Here, we employ spatial proteomics by mass spectrometry and machine learning to map the molecular landscape of AATD in human liver tissue at high resolution. Our approach, combining Deep Visual Proteomics with single-cell analysis in a patient cohort, characterized early and late responses to protein aggregation across fibrosis stages. We achieved a remarkable quantitative depth of 2,800 proteins per single hepatocyte shape, providing detailed insights into cellular heterogeneity. This comprehensive biological dataset revealed an unexpected early integrated peroxisomal upregulation, preceding the canonical unfolded protein response. Our single-cell data demonstrate that alpha-1 antitrypsin accumulation is largely cell-intrinsic, with minimal stress propagation between neighboring hepatocytes. By integrating proteomic data with AI-guided image analysis across multiple disease stages, we identify a terminal hepatocyte phenotype, marked by globular protein aggregates and distinct proteomic signatures including elevated TNFSF10/TRAIL expression. This phenotype may represent a critical stage in disease progression. Our study unveils novel insights into AATD pathogenesis and introduces a powerful methodology for high-resolution, in situ proteomic analysis of complex tissues. This approach holds potential to unravel molecular mechanisms in various protein misfolding disorders and beyond, setting a new standard for understanding disease progression at the single-cell level in human tissue.

Project description:We characterized the transcribed active enhancers of a human neuronal cell line derived from fetal mesencephalon (LUHMES) during differentiation by native elongating transcript-cap analysis of gene expression (NET-CAGE). Raw data files starting from 'Total' are conventional CAGE method outputs, and those starting from 'Nascent' are NET-CAGE method outputs.

Project description:We present One-Tip, a lossless proteomics methodology that seamlessly combines swift, one-pot sample preparation with narrow-window data-independent acquisition mass spectrometric analysis. With simplest sample processing, One-Tip reproducibly identifies > 9,000 proteins from ~1000 cells and ~ 6,000 proteins in a single mouse zygote with a throughput of 40 samples-per-day. This easy-to-use method expands capabilities of proteomics research by enabling greater depth, scalability and throughput covering low to high input samples.

Project description:Small molecule inhibitors of BRAF and MEK have proven effective at inhibiting tumor growth in melanoma patients, however this efficacy is limited due to the almost universal development of drug resistance. To provide advanced insight into the signaling responses that occur following kinase inhibition we have performed quantitative (phospho)-proteomics of human melanoma cells treated with either Dabrafenib, a BRAF inhibitor; Trametinib, a MEK inhibitor or SCH772984, an ERK inhibitor. Over nine experiments we identified 7827 class I phosphosites on 4960 proteins. This included 54 phosphorylation sites that were significantly down-modulated after exposure to all three inhibitors, 34 of which have not been previously reported. Functional analysis of these novel ERK targets identified roles for them in GTPase activity and regulation, apoptosis and cell-cell adhesion. Comparison of the results presented here with previously reported phosphorylation sites downstream of ERK showed a limited degree of overlap suggesting that ERK signaling responses may be highly cell line and cue specific. In addition we identified 26 phosphorylation sites that were only responsive to Dabrafenib. We provide further orthogonal experimental evidence for 3 of these sites in human embryonic kidney cells over-expressing BRAF as well as further computational insights using KinomeXplorer. The validated phosphorylation sites were found to be involved in actin regulation, which has been proposed as a novel mechanism for inhibiting resistance development. These results would suggest that the linearity of the BRAF-MEK-ERK pathway is at least context dependent.

Project description:single cell RNA-Sequencing of Phallusia mammillata embryos from 2-cell to 16-cell stage

Project description:single cell RNA-Sequencing of Phallusia mammillata embryos from 32-cell to 64-cell stage

Project description:This dataset supports the manuscript “Diurnal Rhythm of the Human Plasma Proteome,” which investigates how protein concentrations in human plasma fluctuate over a 24-hour period. Using high-throughput mass spectrometry, we analyzed 208 high-quality plasma samples collected every three hours from 24 healthy individuals under tightly controlled conditions. Out of 523 quantified proteins, 138 (~26%) showed significant diurnal rhythmicity. These proteins were enriched in specific tissues, particularly the liver and platelets, and were involved in key biological pathways including hemostasis, immune signaling, and metabolism. Importantly, 36 clinically relevant biomarkers displayed time-of-day-dependent variation, highlighting the need to incorporate temporal factors in diagnostic and research protocols. This dataset offers valuable insights into circadian regulation of the plasma proteome and provides a resource for researchers studying time-sensitive biomarkers and physiological processes.

Project description:Single-cell proteomics by mass spectrometry (MS) is emerging as a powerful and unbiased method for the characterization of biological heterogeneity. So far, it has been limited to cultured cells, whereas an expansion of the method to complex tissues would greatly enhance biological insights. Here we describe single-cell Deep Visual Proteomics (scDVP), a technology that integrates high-content imaging, laser microdissection and multiplexed MS. scDVP resolves the context-dependent, spatial proteome of murine hepatocytes at a current depth of 1,700 proteins from a slice of a cell. Half of the proteome was differentially regulated in a spatial manner, with protein levels changing dramatically in proximity to the central vein. We applied machine learning to proteome classes and images, which subsequently inferred the spatial proteome from imaging data alone. scDVP is applicable to healthy and diseased tissues and complements other spatial proteomics or spatial omics technologies.

Project description:Early diagnosis of esophageal squamous cell carcinoma (ESCC) is crucial for improving patient prognosis. Currently, the diagnosis of ESCC primarily relies on endoscopic biopsy. Salivary exosomes have shown great potential in non-invasive screening, but their proteomic and lipidomic characteristics remain to be reported. Exosomes were isolated from salivary samples of 54 patients with ESCC and 62 healthy controls using ultracentrifugation, and subsequently subjected to non-targeted proteomic and lipidomic analysis by liquid chromatography-tandem mass spectrometry (LC-MS/MS). Differentially expressed proteins and lipids in salivary exosomes were identified through differential analysis, and a comprehensive analysis of multi-omics data was performed using correlation analysis.

Project description:Spatial tissue proteomics combining microscopy-based cell phenotyping with ultrasensitive mass spectrometry (MS)-based proteomics is an emerging and powerful concept for the study of cell function and heterogeneity in health and disease. However, optimized workflows that preserve morphological information for image-based phenotype discovery and maximize proteome coverage of few or even single cells from laser microdissected archival tissue, are currently lacking. Here, we report a robust and scalable workflow for the proteomic analysis of ultra-low input formalin-fixed, paraffin-embedded (FFPE) material. Benchmarking in the murine liver resulted in up to 2,000 quantified proteins from single hepatocyte contours and nearly 5,000 proteins from 50-cell regions with high quantitative reproducibility. Applied to human tonsil, we profiled 146 microregions including spatially defined T and B lymphocyte niches and quantified cell-type specific markers, cytokines, immune cell regulators and transcription factors. These rich data also highlighted proteome dynamics in spatially defined zones of activated germinal centers, illuminating sites undergoing active B-cell proliferation and somatic hypermutation. Our results demonstrate the power of spatially-resolved proteomics for tissue phenotyping by integrating high-content imaging, laser microdissection, and ultrasensitive mass spectrometry. This approach has broad implications for a wide range of biomedical applications, including early disease profiling, drug target discovery and biomarker research.