Project description:Multimodal imaging by matrix-assisted laser desorption ionisation mass spectrometry imaging (MALDI MSI) and microscopy holds potential for understanding pathological mechanisms by mapping molecular signatures from the tissue micro environment to specific cell populations. However, existing software solutions for MALDI MSI data analysis are incomplete, require programming skills and contain laborious manual steps, hindering broadly applicable, reproducible, and high throughput analysis to generate impactful biological discoveries. Here we present msiFlow, an accessible open-source, platform-independent and vendor-neutral software for end-to-end, high-throughput, transparent and reproducible analysis of multi modal imaging data. msiFlow integrates all necessary steps from raw data import to analysis visualization along with state-of-the-art and newly developed algorithms into automated workflows. Using msiFlow, we unravel the molecular heterogeneity of leukocytes in infected tissues by spatial regulation of ether-linked phospholipids containing arachidonic acid. We anticipate that msiFlow will facilitate the broad applicability of MSI in multi modal imaging to uncover context-dependent cellular regulations in disease states.

Project description:Spatial metabolomics describes the location and chemistry of small molecules involved in metabolic phenotypes, defense molecules and chemical interactions in natural communities. Most current techniques are unable to spatially link the genotype and metabolic phenotype of microorganisms in situ at a scale relevant to microbial interactions. Here, we present a spatial metabolomics pipeline (metaFISH) that combines fluorescence in situ hybridization (FISH) microscopy and high-resolution atmospheric pressure mass spectrometry imaging (AP-MALDI-MSI) to image host-microbe symbioses and their metabolic interactions. metaFISH aligns and integrates metabolite and fluorescent images at the micrometer-scale for a spatial assignment of host and symbiont metabolites on the same tissue section. To illustrate the advantages of metaFISH, we mapped the spatial metabolome of a deep-sea mussel and its intracellular symbiotic bacteria at the scale of individual epithelial host cells. Our analytical pipeline revealed metabolic adaptations of the epithelial cells to the intracellular symbionts, a variation in metabolic phenotypes in one symbiont type, and novel symbiosis metabolites. metaFISH provides a culture-independent approach to link metabolic phenotypes to community members in situ - a powerful tool for microbiologists across fields. <br><br> <b>UPLC-MS/MS assay</b> protocols and data are reported in the current study <b>MTBLS746</b>. <br><br> <b>MALDI imaging MS assay</b> protocols and data associated to this study are reported in <a href="https://www.ebi.ac.uk/metabolights/MTBLS744"><b>MTBLS744</b></a>.<br> <b>On-tissue MALDI imaging MS/MS assay</b> protocols and data associated to this study are reported in <a href="https://www.ebi.ac.uk/metabolights/MTBLS805"><b>MTBLS805</b></a>.<br> <b>MRMS assay</b> protocols and data associated to this study are reported in <a href="https://www.ebi.ac.uk/metabolights/MTBLS811"><b>MTBLS811</b></a>.<br>

Project description:Spatial metabolomics describes the location and chemistry of small molecules involved in metabolic phenotypes, defense molecules and chemical interactions in natural communities. Most current techniques are unable to spatially link the genotype and metabolic phenotype of microorganisms in situ at a scale relevant to microbial interactions. Here, we present a spatial metabolomics pipeline (metaFISH) that combines fluorescence in situ hybridization (FISH) microscopy and high-resolution atmospheric pressure mass spectrometry imaging (AP-MALDI-MSI) to image host-microbe symbioses and their metabolic interactions. metaFISH aligns and integrates metabolite and fluorescent images at the micrometer-scale for a spatial assignment of host and symbiont metabolites on the same tissue section. To illustrate the advantages of metaFISH, we mapped the spatial metabolome of a deep-sea mussel and its intracellular symbiotic bacteria at the scale of individual epithelial host cells. Our analytical pipeline revealed metabolic adaptations of the epithelial cells to the intracellular symbionts, a variation in metabolic phenotypes in one symbiont type, and novel symbiosis metabolites. metaFISH provides a culture-independent approach to link metabolic phenotypes to community members in situ - a powerful tool for microbiologists across fields. <br><br> <b>MALDI imaging MS assay</b> protocols and data are reported in the current study <b>MTBLS744</b>. <br><br> <b>UPLC-MS/MS assay</b> protocols and data associated to this study are reported in <a href=https://www.ebi.ac.uk/metabolights/MTBLS746><b>MTBLS746</b></a>.<br> <b>On-tissue MALDI imaging MS/MS assay</b> protocols and data associated to this study are reported in <a href=https://www.ebi.ac.uk/metabolights/MTBLS805><b>MTBLS805</b></a>.<br> <b>MRMS assay</b> protocols and data associated to this study are reported in <a href=https://www.ebi.ac.uk/metabolights/MTBLS811><b>MTBLS811</b></a>.<br>

Project description:Spatial metabolomics describes the location and chemistry of small molecules involved in metabolic phenotypes, defense molecules and chemical interactions in natural communities. Most current techniques are unable to spatially link the genotype and metabolic phenotype of microorganisms in situ at a scale relevant to microbial interactions. Here, we present a spatial metabolomics pipeline (metaFISH) that combines fluorescence in situ hybridization (FISH) microscopy and high-resolution atmospheric pressure mass spectrometry imaging (AP-MALDI-MSI) to image host-microbe symbioses and their metabolic interactions. metaFISH aligns and integrates metabolite and fluorescent images at the micrometer-scale for a spatial assignment of host and symbiont metabolites on the same tissue section. To illustrate the advantages of metaFISH, we mapped the spatial metabolome of a deep-sea mussel and its intracellular symbiotic bacteria at the scale of individual epithelial host cells. Our analytical pipeline revealed metabolic adaptations of the epithelial cells to the intracellular symbionts, a variation in metabolic phenotypes in one symbiont type, and novel symbiosis metabolites. metaFISH provides a culture-independent approach to link metabolic phenotypes to community members in situ - a powerful tool for microbiologists across fields. <br><br> <b>MRMS assay</b> protocols and data are reported in the current study <b>MTBLS811</b>.<br><br> <b>MALDI imaging MS assay</b> protocols and data associated to this study are reported in <a href="https://www.ebi.ac.uk/metabolights/MTBLS744"><b>MTBLS744</b></a>.<br> <b>UPLC-MS/MS assay</b> protocols and data associated to this study are reported in <b><a href="https://www.ebi.ac.uk/metabolights/MTBLS746">MTBLS746</a></b>.<br> <b>On-tissue MALDI imaging MS/MS assay</b> protocols and data associated to this study are reported in <b><a href="https://www.ebi.ac.uk/metabolights/MTBLS805">MTBLS805</a></b>.<br>

Project description:Spatial metabolomics describes the location and chemistry of small molecules involved in metabolic phenotypes, defense molecules and chemical interactions in natural communities. Most current techniques are unable to spatially link the genotype and metabolic phenotype of microorganisms in situ at a scale relevant to microbial interactions. Here, we present a spatial metabolomics pipeline (metaFISH) that combines fluorescence in situ hybridization (FISH) microscopy and high-resolution atmospheric pressure mass spectrometry imaging (AP-MALDI-MSI) to image host-microbe symbioses and their metabolic interactions. metaFISH aligns and integrates metabolite and fluorescent images at the micrometer-scale for a spatial assignment of host and symbiont metabolites on the same tissue section. To illustrate the advantages of metaFISH, we mapped the spatial metabolome of a deep-sea mussel and its intracellular symbiotic bacteria at the scale of individual epithelial host cells. Our analytical pipeline revealed metabolic adaptations of the epithelial cells to the intracellular symbionts, a variation in metabolic phenotypes in one symbiont type, and novel symbiosis metabolites. metaFISH provides a culture-independent approach to link metabolic phenotypes to community members in situ - a powerful tool for microbiologists across fields. <br><br> <b>On-tissue MALDI imaging MS/MS assay</b> protocols and data are reported in the current study <b>MTBLS805</b>.<br><br> <b>MALDI imaging MS assay</b> protocols and data associated to this study are reported in <a href="https://www.ebi.ac.uk/metabolights/MTBLS744"><b>MTBLS744</b></a>.<br> <b>UPLC-MS/MS assay</b> protocols and data associated to this study are reported in <a href="https://www.ebi.ac.uk/metabolights/MTBLS746"><b>MTBLS746</b></a>.<br> <b>MRMS assay</b> protocols and data associated to this study are reported in <a href="https://www.ebi.ac.uk/metabolights/MTBLS811"><b>MTBLS811</b></a>.<br>

Project description:Spatial genome organization is essential to direct fundamental DNA-templated biological processes (e.g. transcription, replication, and repair), but the 3D in situ nanometer-scale structure of accessible cis-regulatory DNA elements within the crowded nuclear environment remains elusive. Here, we combined the recently developed Assay for Transposase-Accessible Chromatin with visualization (ATAC-see), PALM super-resolution imaging and lattice light-sheet microscope (a method termed 3D ATAC-PALM) to selectively image and quantitatively analyze key features of the 3D accessible genome in single cells. 3D ATAC-PALM reveals that accessible chromatin are non-homogeneously organized into spatially segregated clusters or accessible chromatin domains (ACDs). To directly link imaging and genomic data, we optimized multiplexed imaging of 3D ATAC-PALM with Oligopaint DNA-FISH, RNA-FISH and protein fluorescence. We found that ACDs colocalize with active chromatin and enclose transcribed genes. By applying these methods to analyze genetically purterbed cells, we demonstrated that genome architectural protein CTCF prevents excessive clustering of accessible chromatin and decompacts ACDs. These results highlight the 3D ATAC-PALM as a useful tool to probe the structure and organizing mechanism of the genome.

Project description:To build a pre-cancer atlas for melanoma that reveals early events in disease initiation and immune response, we performed RNA sequencing of 222 histologically distinct micro-regions (~5-20 cells per region) extracted from 3 formalin-fixed paraffin-embedded tissue sections collected from a melanoma patient. These sections capture multiple phases of disease progression from melanoma in situ to metastatic invasive melanoma and areas of effective immune surveillance. Micro-region transcript data is complemented by sub-cellular resolution imaging using tissue-based cyclic immunofluorescence and will be released via the Human Tumor Atlas data portal.

Project description:N-linked glycans are structurally diverse polysaccharides that represent significant biological relevance due to their involvement in disease progression and cancer. Due to their complex nature, N-linked glycans pose many analytical challenges requiring the continued development of analytical technologies. Infrared matrix-assisted laser desorption electrospray ionization (IR-MALDESI) is a hybrid ionization technique commonly used for mass spectrometry imaging (MSI) applications. Previous work demonstrated IR-MALDESI to significantly preserve sialic acid containing N-linked glycans that otherwise require chemical derivatization prior to detection. Here we demonstrate the first analysis of N-linked glycans in situ by IR-MALDESI MSI. Formalin-fixed paraffin-embedded (FFPE) human prostate tissue was analyzed in negative ionization mode after tissue washing, antigen retrieval, and pneumatic application of PNGase F for enzymatic digestion of N-linked glycans. 53 N-linked glycans were confidently identified in the prostate sample where more than 60% contained sialic acid residues. This work demonstrates the first steps in N-linked glycan imaging of biological tissues by IR-MALDESI MSI.

Project description:Conjoined parasitic twins in a free ranging Northern bat (Eptesicus nilssonii) from Norway: a micro-CT anatomic and genetic survey

Project description:Three-dimensional imaging mass spectrometry (3D imaging MS) is a technique of analytical chemistry for 3D molecular analysis of a tissue specimen, entire organ, or microbial colonies on an agar plate. 3D imaging MS has unique advantages over existing 3D imaging techniques, offers novel perspectives for understanding the spatial organization of biological processes, and has growing potential to be introduced into routine use in both biology and medicine. Due to the sheer quantity of data generated, visualization, analysis, and interpretation of 3D imaging MS data remain a significant challenge. Bioinformatics research in this field is hampered by the lack of publicly available benchmark datasets needed for evaluation and comparison of algorithms. Findings We acquired high-quality 3D imaging MS datasets from different biological systems at several labs, supplied them with overview images and scripts demonstrating how to read them, and deposited them into MetaboLights, an open repository for metabolomics data. 3D imaging MS data was collected from five samples using two types of 3D imaging MS. 3D Matrix-Assisted Laser Desorption/Ionization (MALDI) imaging MS data was collected from murine pancreas, murine kidney, human oral squamous cell carcinoma, and interacting microbial colonies cultured in Petri dishes. 3D Desorption Electrospray Ionization (DESI) imaging MS data was collected from a human colorectal adenocarcinoma. Conclusions With the aim to stimulate computational research in the field of computational 3D imaging MS, we provided selected high-quality 3D imaging MS datasets which can be used by algorithm developers as benchmark datasets.