Project description:The Nanopig™ model is an emerging non-rodent platform for (bio)pharmaceutical safety assessment, with potential advantages for translational research. Here, we report initial characterization results using whole genome sequencing (WGS) and tissue-based proteomics, focusing on drug metabolism and immune system relevance. WGS produced a high-quality Nanopig™ genome assembly (2.8–2.9 Gb), with >98 % alignment to the Duroc pig reference genome, and identified key metabolic and immune-related genes, including 47 cytochrome P450 (CYP450) genes with high homology to human CYP450 families. Proteomic profiling of 15 pharmaceutically relevant tissues revealed human orthologous drug metabolism enzymes and transporters (DMETs), as well as immune-related proteins, indicating similarities to human CYP450 enzyme abundance and tissue distribution. Functional evaluation of hepatic CYP450 activity yielded kinetic parameters (Km, Vmax) in the range observed in humans and beagle dogs. These early findings represent a foundational multi-omics dataset for the Nanopig™, suggesting its future use as a translational model in preclinical safety assessment. This work provides an early framework for species selection strategies and model optimization, with the long-term goal of reducing reliance on traditional non-rodent species in drug development.

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.

Project description:Opportunistic infections of the respiratory tract often succeed under a weakened immune response caused by an underlying illness or hospitalization. The human fungal pathogen, Cryptococcus neoformans, and the bacterial pathogen, Klebsiella pneumoniae, are both well-characterized microbes that cause severe infections within immunocompromised individuals. In this study, we simulate a concentration-dependent pulmonary coinfection of a bacterial and fungal pathogen, and profile the proteomic changes by DDA vs. DIA. Dual perspective profiling provides new insights into host defense regulation of infection and pathogenic mechanisms of invasion.

Project description:Denver Health has conducted the Control of Major Bleeding After Trauma (COMBAT) clinical research study, which aimed to improve trauma care for all patients (https://www.denverhealth.org/services/trauma/for-professionals-2/research-publications/combattrial). The study began in April 2014 and concluded in March of 2017. In collaboration with the University of Colorado Anschutz Medical Campus, longitudinal plasma samples collected from the COMBAT trial were analyzed by MS-based proteomics and metabolomics (available on Metabolomics Workbench).

Project description:Generation of a new library of targeted mass spectrometry assays for accurate protein quantification in triple negative breast cancer (TNBC) tissues. Primary tumor tissue lysates from 105 TNBC patients treated at Masaryk Memorial Cancer Institute (MMCI) in Brno, Czech Republic, were used to generate the spectral library. This project covers raw files from data-dependent acquisition (DDA) – parallel accumulation-serial fragmentation (PASEF) measurements of 12 hydrophilic chromatography (HILIC) fractions of aliquot pool from complete set of 105 samples measured on timsTOF Pro; raw files of 16 individual samples measured in data-independent acquisition (DIA) – PASEF mode and used for hybrid library generation and for demonstrative quantitative DIA data extraction; Pulsar archive generated in Spectronaut 16.0 from 12 DDA-PASEF measurements of HILIC fractions and from 16 data-independent acquisition DIA-PASEF measurements of individual samples. The 16 DIA-PASEF runs of individual samples used for library generation were analyzed using newest versions of Spectronaut (version 18.5) and DIA-NN (version 1.8.1) software tools in library-based setting using the newly generated library as well as in library-free setting showing library-based method to outperform the use of predicted libraries in the terms of identification numbers.

Project description:Mitochondrial dysfunction is associated with inflammatory bowel diseases (IBD). To understand how microbial-metabolic circuits contribute to intestinal tissue injury, we disrupt mitochondrial function in the intestinal epithelium by deleting heat shock protein 60 (Hsp60Δ/ΔIEC). While metabolic perturbation causes self-resolving tissue injury, regeneration is disrupted in the absence of aryl hydrocarbon receptor (Hsp60Δ/ΔIEC;AhR-/-) or IL-10 (Hsp60Δ/ΔIEC;Il10-/-) leading to IBD-like pathology. Tissue pathology is absent in the distal colon of germfree (GF) Hsp60Δ/ΔIEC mice, highlighting bacterial control of metabolic injury. Selective colonization of GF Hsp60Δ/ΔIEC mice with the synthetic community OMM12 confirms expansion of metabolically-flexible Bacteroides ssp., which generates metabolic injury in mono-colonized mice. Transcriptional profiling of metabolically-impaired epithelium identifies gene signatures, such as Ido1, Nos2, and Duox2, differentiating active from inactive tissue inflammation in 343 tissue sections from Crohn’s disease patients. In conclusion, mitochondrial perturbation of the epithelium causes microbiota-dependent tissue injury and discriminative inflammatory gene profiles with relevance for IBD.

Project description:The proximal region of the oviduct (isthmus) serves as a sperm reservoir in many mammalian species. This reservoir is composed of epithelial cells that bind sperm primarily to their apical cilia and ensure the survival of high-quality sperm until ovulation. The species-specific molecular interactions between spermatozoa and the oviduct epithelium, however, are still poorly understood. The aim of this study is to identify new candidates for sperm-interacting proteins in the bovine reservoir using laser capture proteomics. Ipsilateral oviducts were collected from cyclic cows at pre- and post-ovulatory stages. Isthmus and ampulla tissue samples were fixed, paraffin embedded, sectioned and subjected to laser microdissection to establish pools of microsamples separating the apical part of the epithelium, containing potential sperm-interacting proteins, from the basal part, containing proteins not currently located or secreted on the cell surface. Proteins were analyzed by nanoLC-MS/MS, and differentially abundant proteins (DAPs) were identified using t-tests. 505 and 512 proteins could be identified in apical and basal microsamples, respectively. Only 8/141 regional and 1/79 cycle stage-related DAPs were shared between the two epithelium parts, indicating a selective regulation of protein expression. Among the apical proteins, 19 were predicted to be candidates for sperm interactions, including annexins (ANXA) 1, 2, 5 and 8, oviduct glycoprotein 1 (OVGP1), voltage-dependent anion-selective channel proteins (VDAC) 1 and 2, and apolipoprotein A1 (APOA1). This work provides the first proteomic characterization of microdissected cellular compartments of the bovine oviduct epithelium and presents new candidates for improving sperm quality in assisted reproductive technologies.

Project description:The diagnosis of Amyotrophic Lateral Sclerosis (ALS) primarily relies on clinical findings and remains challenging, particularly in the early stages of the disease, where characteristic symptoms may be subtle and nonspecific. Therefore, the development of disease-specific and clinically validated biomarkers is crucial to enhance diagnostic precision and optimize patient management. Here, we explored tear fluid (TF) as a promising biomarker source for ALS, given its accessibility, prior evidence of discriminative power in other neurodegenerative diseases, and its anatomical proximity to the brainstem as an important site of neurodegeneration. Using a discovery-based approach, we profiled protein abundance in TF of 49 ALS patients and 54 controls via data-independent acquisition mass spectrometry (DIA-MS) Biostatistical analysis and machine learning identified a signature of six proteins with diagnostic potential (AUROC = 66.2%).

Project description:Myocardial infarction (MI) continues to be a leading cause of death worldwide. Even though it is well-established that the complex interplay between different cell types determines the overall healing response after MI, the precise changes in the tissue architecture are still poorly understood. Here we generated an integrative cellular map of the acute phase after murine MI using a combination of imaging-based transcriptomics (Molecular Cartography) and antibody-based highly multiplexed imaging (Sequential Immunofluorescence), which enabled us to evaluate cell-type compositions and changes at subcellular resolution over time. One striking finding of these analyses was the identification of a novel mode of leukocyte accumulation to the infarcted heart via the endocardium - the inner layer of the heart. To investigate the underlying mechanisms driving this previously unknown infiltration route, we performed unbiased spatial proteomic analysis using Deep Visual Proteomics (DVP). When comparing endocardial cells of homeostatic hearts and infarcted hearts, DVP identified von Willebrand Factor (vWF) as an upregulated mediator of inflammation 24 hours post MI. To further explore the immune mediating capabilities of vWF and its effect on tissue repair, we performed functional blocking of vWF during acute murine MI. This resulted in a reduced amount of infiltration by CCR2+ monocytes and worse cardiac function post-MI. Our study provides the first spatial map of acute murine MI with subcellular resolution and subsequently discovers a novel route of immune infiltration. Furthermore, we identified vWF as a critical immune mediating agent for endocardial immune cell infiltration.

Project description:We performed shallow whole genome sequencing (WGS) on circulating free (cf)DNA extracted from plasma or cerebrospinal fluid (CSF), and shallow WGS on the tissue DNA extracted from the biopsy in order to evaluate the correlation between the two biomaterials. After library construction and sequencing (Hiseq3000 or Ion Proton), copy number variations were called with WisecondorX.