Project description:Mass spectrometry imaging (MSI) can analyze the spatial distribution of hundreds of different molecules directly from tis-sue sections usually placed on conductive glass slides to provide conductivity on the sample surface. Additional experiments are often required for molecular identification using consecutive sections on membrane slides compatible with laser capture microdissection (LMD). In this work, we demonstrate for the first time the use of a single conductive slide for both matrix assisted laser desorption ionization (MALDI)-MSI and direct proteomics. In this workflow, regions of interest can be directly ablated with LMD while preserving protein integrity. These results offer an alternative for MSI based multimodal spatial-omics.

Project description:Lipidomics, proteomics and metabolomics characterization of the ontogeny of lipid, protein and metabolite changes during normal postnatal lung development

Project description:Mass spectrometry imaging (MSI) allows investigating the spatial distribution of chemical compounds directly in biological tissues. As the analytical depth of MSI is limited, MSI needs to be coupled to more sensitive local extraction-based omics approaches to achieve a comprehensive molecular characterization. For this it is important to retain the spatial information provided by MSI for follow-up omics studies. It has been shown that regiospecific MSI data can be used to guide a laser microdissection system (LMD) for ultra-sensitive LC-MS analyses. So far, this combination has required separate and specialized MS instrumentation. Recent advances in dual-source instrumentation, harboring both MALDI and ESI sources, promise state-of-the-art MSI and liquid-based proteomic capabilities on the same MS instrument. In this study, we demonstrate that such an instrument can offer both, fast lipid-based MSI at high mass- and high lateral resolution, and sensitive LC-MS on local protein extracts from the exact same tissue section.

Project description:Oxidative stress is induced by various natural abiotic factors including irradiation among many microorganisms and has been demonstrated that it significantly improved growth rate and lipid production of R. glutinis. However, the specific mechanisms of how irradiation influence the metabolism of R. glutinis remains still unavailable. To investigate and better understand the mechanisms involved in irradiation-induced stress resistance in R. glutinis, a multi-omics metabolism analysis was implemented. The results confirmed that irradiation indeed not only improve cell biomass but also accelerate carotenoids and lipid production, especially neutral lipid. Compared with the control, metabolome profiling in the group exposed to irradiation exhibited obvious difference in the activation of TCA cycle and transition of glucose utilization pattern from glycolysis to pentose phosphate pathway. The results of proteome showed that 423 proteins were changed significantly and proteins associated with protein folding and transport, the Hsp40 and Sec12, were obviously up-regulated, indicating that cells responded to irradiation by accelerating the protein folding and transport of correctly folded proteins as well as enhanced the degradation of misfolded proteins. A significant up-regulation of carotenoids biosynthetic pathway was observed which revealed that increased carotenoids is a cellular defense mechanism against oxidative stress generated by irradiation. Therefore, the results of comprehensive omics analysis provide new insights on the response and tolerance mechanism of R. glutinis to irradiation-induced oxidative stress resistance and could be helpful in the further investigation of R. glutinis as model microorganism for biofuel production.

Project description:During aging, the kidney undergoes functional and physiological changes that are closely affiliated with chronic kidney disease (CKD). There is increasing evidence supporting the role of lipid or lipid-derived mediators in the pathogenesis of CKD and other aging-related diseases. To understand the role of lipids in various metabolic processes during kidney aging, we conducted MALDI imaging mass spectrometry (MALDI-IMS) analysis in kidneys harvested from young (2 months old, n=3) and old mice (24 months old, n=3). MALDI-IMS analysis showed an increase in ceramide level and a decrease in sphingomyelin (SM) and phosphatidylcholine (PC) levels in kidneys of old mice. The increased expression of cPLA2 and SMPD1 protein in aged kidney was confirmed by immunohistochemistry and western blot analysis. Our MALDI-IMS data showed the altered distribution of lipids in aged kidney as indicative of aging-related functional changes of the kidney. Combined analysis of MALDI-IMS and IHC confirmed lipidomic changes and expression levels of responsible enzymes as well as morphological changes.

Project description:MH-GRID Consortium

Project description:MH-GRID Consortium

Project description:MH-GRID 2.0

Project description:After performing MALDI metabolomics analysis, we identified airway regions. On a consecutive slide we used laser capture microdissection (LCM) to cut out regions of interest that had an airway specific signal by MALDI. The samples were prepped using the MicroPOTS protocol (PMID: 33491460) and analyzed by LC-MS/MS. The search was performed using MaxQuant and both LFQ and iBAQ quantification were performed.

Project description:LC-MS/MS (LTQ-Orbitrap, CID) data sets of 31 human ovarian cancer samples (FFPE). Sample material obtained by laser microdissection of cores from tissue microarray. Preparation matching MALDI imaging protocol (as described in Gustafsson, J Proteomics 2012).