Abstract
Current histological and anatomical analysis techniques, including fluorescence in situ hybridisation, immunohistochemistry, immunofluorescence, immunoelectron microscopy and fluorescent fusion protein, have revealed great distribution diversity of mRNA and proteins in the brain. However, the distributional pattern of small biomolecules, such as lipids, remains unclear. To this end, we have developed and optimised imaging mass spectrometry (IMS), a combined technique incorporating mass spectrometry and microscopy, which is capable of comprehensively visualising biomolecule distribution. We demonstrated the differential distribution of phospholipids throughout the cell body and axon of neuronal cells using IMS analysis. In this study, we used solarix XR, a high mass resolution and highly sensitive MALDI-FT-ICR-MS capable of detecting higher number of molecules than conventional MALDI-TOF-MS instruments, to create a molecular distribution dataset. We examined the diversity of biomolecule distribution in rat brains using IMS and hypothesised that unsupervised machine learning reconstructs brain structures such as the grey and white matters. We have demonstrated that principal component analysis (PCA) can reassemble the grey and white matters without assigning brain anatomical regions. Hierarchical clustering allowed us to classify the 10 groups of observed molecules according to their distributions. Furthermore, the group of molecules specifically localised in the cerebellar cortex was estimated to be composed of phospholipids.
Highlights
The mammalian brain is composed of a multitude of cell types, and its spatial structure is commensurately highly complex
We hypothesise that principal component analysis (PCA) was able to reconstruct the distributions of molecules localised in the grey and white matters
Imaging mass spectrometry (IMS) analyses were conducted using a solarix XR Matrix Assisted Laser Desorption/Ionisation (MALDI)-IMS instrument furnished with FT-ICR-MS
Summary
The mammalian brain is composed of a multitude of cell types, and its spatial structure is commensurately highly complex. The distributions of biomolecules in the brain can be analysed using several techniques Among these are radioisotope and fluorescent tagging, with applicable spatial resolutions ranging between those of optical microscopy www.nature.com/scientificreports/. Through a combination of histological techniques, e.g. laser microdissection and micro-extraction, mass spectrometry can analyse tissue-specific compositions of biomolecules[31,32] These approaches have high detection sensitivity of biomolecules, but their spatial resolutions are several hundred micrometres. We recently demonstrated that the compositions of biomolecules are highly similar in different areas of the same tissues and even within different organs[41] These previous findings led us to the possibility that it can classify the distributions of biomolecules in the brain at least as three groups: in white matter, in grey matter and homogeneously expressed. We challenged to investigate the diversity of molecule distributions in the brain
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