Project description:Multimodal mass spectrometry imaging (MSI) is a critical technique used for deeply investigating biological systems by combining multiple MSI platforms in order to gain the maximum molecular information about a sample that would otherwise be limited by a single analytical technique. The aim of this work was to create a multimodal MSI approach that measures metabolomic and proteomic data from a single biological organ by combining infrared matrix-assisted laser desorption electrospray ionization (IR-MALDESI) for metabolomic MSI and nanodroplet processing in one pot for trace samples (nanoPOTS) LC-MS/MS for spatially resolved proteome profiling. Adjacent tissue sections of rat brain were analyzed by each platform and each dataset was individually analyzed using previously optimized workflows. IR-MALDESI datasets were annotated by accurate mass and spectral accuracy using HMDB, METLIN, and LipidMaps databases, while nanoPOTS-LC-MS/MS datasets were searched against the rat proteome using the Sequest HT algorithm and filtered with a 1% FDR. The combined data revealed complementary molecular profiles distinguishing the corpus collosum against other sampled regions of the brain. A multiomic pathway integration showed a strong correlation between the two datasets when comparing average abundances of metabolites and corresponding enzymes in each brain region. This work demonstrates the first steps in the creation of a multimodal MSI technique that combines two highly sensitive and complementary imaging platforms.

Project description:We developed and validated ‘HIT-MAP’ (High-resolution Informatics Toolbox in MALDI-MSI Proteomics), an open-source bioinformatics workflow using peptide mass fingerprint analysis and a dual scoring system to computationally assign peptide and protein annotations to high mass resolution MSI datasets, and generate customisable spatial distribution maps. The uploaded files are an example dataset for the HiTMaP proteomics search engine, designed for MALDI-imaging proteomics annotation. The example data files contain one bovine lens tissue section and one mouse brain tissue section. The ID folder contains the protein/peptide identification result for each tissue segment, and the summary folder contains the protein cluster images.

Project description:Tissue Top-down microproteomic was performed on 3 brain regions. 156 references proteins from different cellular compartments were characterized. Moreover, 11 Alternative proteins issued from alternative open reading frames (AltORF) were identified and were relied to the brain regions and associated to the function of their reference proteins. Some proteins display specific post-translational modifications profiles or truncation linked the brain regions and their functions. Systemic biology performed on microproteome identified in each region allowed to associate sub-networks with functional physiology of each brain region. Back correlation of the local extracted and identified microproteome with tissue cellular localization was then performed by MALDI mass spectrometry imaging. 40 proteins including 4 Altproteins have been back correlated in MALDI MSI and are in line with their tissue extracted region and physiological function. Taken together, we established the molecular physiome of 3 rat brain regions through reference and hidden proteome characterization.

Project description:MALDI mass spectrometry imaging (MSI) enables label-free, spatially resolved analysis of a wide range of analytes in tissue sections. Quantitative analysis of MSI datasets is typically performed on single pixels or manually assigned regions of interest (ROI). However, many sparse, small objects such as Alzheimer’s disease (AD) brain deposits of amyloid peptides called plaques are neither single pixels nor ROI. Here, we propose a new approach to facilitate comparative computational evaluation of amyloid plaque-like objects by MSI: a fast PLAQUE PICKER tool that enables statistical evaluation of heterogeneous amyloid peptide composition. Comparing two AD mouse models, APP NL-G-F and APP PS1, we identified distinct heterogeneous plaque populations in the NL-G-F model, but only one class of plaques in the PS1 model. We propose quantitative metrics for the comparison of technical and biological MSI replicates.

Project description:Five microarrays from a larger dataset used to demonstrate a normalization technique base on Zipf's law. The original data set was generated by using Atlas Rat cDNA microarrays (Clontech, 588 genes) probed with rat brain tissue, from control (cerebellum n=10, olive n=10) and harmaline treated (cerebellum n=10, olive n=9) animals. Microarrays were probed according to established protocols and exposed to imaging plates overnight (BAS-MS 2325) and scanned at a 50 m resolution on a FLA-3000G phosphoimager (Raytest, Germany). Image gridding was carried out using VisualGrid® software (http://www.gpc-biotech.com).

Project description:We have developed an imaging-free framework to localize nucleic acids within a tissue by combining  a compressed sensing tissue-sampling strategy based on multi-angle-sectioning and an associated image reconstruction algorithm.  Initially, the tissue is cut into consecutive thin slices. Subsequently these are further sliced along an orthogonal plane at predefined orientations resulting in tissue strips that are subject to RNA sequencing. We implemented this framework to transform a single-cell RNA sequencing protocol into an imaging-free spatial transcriptomics technique. The method was validated by profiling the transcriptome of the Murine brain, and used to spatially profile the brain transcriptome of the Australian Central bearded dragon, Pogona vitticeps.

Project description:<p>Mass spectrometry imaging (MSI) is a molecular imaging technique that maps the distribution of molecules in biological tissues with high spatial resolution. The most widely used MSI modality is matrix-assisted laser desorption/ionization (MALDI), but some organic matrices used in classical MALDI may impact the quality of the molecular images due to limited lateral resolution and strong background noise in the low mass range, hindering its use in metabolomics. Here we present a matrix-free LDI technique based on the deposition by sputtering of gold nanolayers on tissue sections. This gold coating method is quick, fully automated and repetitive and allows growing highly controlled nanolayers, necessary for high quality and high resolution MS image acquisition. The performance of the developed method has been tested on the acquisition of MS images of brain. The obtained spectra showed a high number of MS peaks on the low mass region (m/z below 1000 Da) with few background peaks, demonstrating the viability of the sputtered gold nanolayers of promoting the desorption/ionization of a wide range of metabolites. These results, together with the reliable MS spectrum calibration using gold peaks, make the developed method a valuable alternative for MSI applications.</p><p><br></p><p><strong>Liver MALDI MS imaging assay</strong> is reported in the current study <a href='https://www.ebi.ac.uk/metabolights/MTBLS589' rel='noopener noreferrer' target='_blank'><strong>MTBLS589</strong></a>.</p><p><strong>Brain MALDI MS imaging assay</strong> is reported in <a href='https://www.ebi.ac.uk/metabolights/MTBLS588' rel='noopener noreferrer' target='_blank'><strong>MTBLS588</strong></a>.</p>

Project description:INTRODUCTION: Mass Spectrometry Imaging (MSI) is a hybrid mass spectrometry technique that integrates aspects of traditional microscopy and mass spectrometry-based omics analysis. The traditional MALDI TOF/TOF instrument still remains the dominant platform for this type of anal-ysis. However, with reduced mass resolution compared to other platforms it is insufficient to rely on mass resolution alone for peptide identification. Here we propose a hybrid method of data analysis that integrates both image-based analysis and a parallel protein identification workflow using peptide mass fingerprinting, and its successful application to the detection and validation of viral biomarkers. METHODS: FFPE samples were imaged as described previously in an UltrafleXtreme MALDI TOF/TOF. Total mass spectra were exported and searched against the mouse FASTA da-tabase, while companion images were exported and processed with image J. RESULTS: Peptide mass fingerprinting (PMF) revealed 14 target peptides that were successfully assigned to viral proteins while a pixel based correlational analysis revealed a very high R2 correlation (>0.81) be-tween those same peptides assigned to the NS1 and VP1 viral proteins. CONCLUSIONS: We successfully identified and validated the presence of viral biomarkers to a high degree of confidence using MALDI MSI.

Project description:<p>Mass spectrometry imaging (MSI) is a molecular imaging technique that maps the distribution of molecules in biological tissues with high spatial resolution. The most widely used MSI modality is matrix-assisted laser desorption/ionization (MALDI), mainly due to the large variety of analyte classes amenable for MALDI analysis. However, the organic matrices used in classical MALDI may impact the quality of the molecular images due to limited lateral resolution and strong background noise in the low mass range, hindering its use in metabolomics. Here we present a matrix-free laser desorption/ionization (LDI) technique based on the deposition of gold nanolayers on tissue sections by means of sputter-coating. This gold coating method is quick, fully automated, reproducible, and allows growing highly controlled gold nanolayers, necessary for high quality and high resolution MS image acquisition. The performance of the developed method has been tested through the acquisition of MS images of brain tissues. The obtained spectra showed a high number of MS peaks in the low mass region (m/z below 1000 Da) with few background peaks, demonstrating the ability of the sputtered gold nanolayers of promoting the desorption/ionization of a wide range of metabolites. These results, together with the reliable MS spectrum calibration using gold peaks, make the developed method a valuable alternative for MSI applications.</p><p><br></p><p><strong>Brain MALDI MS imaging assay</strong> is reported in the current study <a href='https://www.ebi.ac.uk/metabolights/MTBLS588' rel='noopener noreferrer' target='_blank'><strong>MTBLS588</strong></a>.</p><p><strong>Liver MALDI MS imaging assay</strong> is reported in <a href='https://www.ebi.ac.uk/metabolights/MTBLS589' rel='noopener noreferrer' target='_blank'><strong>MTBLS589</strong></a>.</p>

Project description:Five microarrays from a larger dataset used to demonstrate a normalization technique base on Zipf's law. The original data set was generated by using Atlas Rat cDNA microarrays (Clontech, 588 genes) probed with rat brain tissue, from control (cerebellum n=10, olive n=10) and harmaline treated (cerebellum n=10, olive n=9) animals. Microarrays were probed according to established protocols and exposed to imaging plates overnight (BAS-MS 2325) and scanned at a 50 m resolution on a FLA-3000G phosphoimager (Raytest, Germany). Image gridding was carried out using VisualGrid® software (http://www.gpc-biotech.com). Keywords: other