Quantitative mass spectrometric analysis of the mouse cerebral cortex after ischemic stroke

Ischemic strokes result in the death of brain tissue and a wave of downstream effects, often leading to lifelong disabilities or death. However, the underlying mechanisms of ischemic damage and repair systems remain largely unknown. In order to better understand these mechanisms, TMT-isobaric mass t...

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Veröffentlicht in:	PloS one 2020-04, Vol.15 (4), p.e0231978
Hauptverfasser:	Agarwal, Ank, Park, Seongje, Ha, Shinwon, Kwon, Ji-Sun, Khan, Mohammed Repon, Kang, Bong Gu, Dawson, Ted M, Dawson, Valina L, Andrabi, Shaida A, Kang, Sung-Ung
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Sprache:	eng
Schlagworte:	Adenosine diphosphate Biology and Life Sciences Brain Brain research Cell death Cerebral blood flow Cerebral cortex Disabilities Engineering Functional groups Gene expression Ischemia Labeling Marking Mass spectrometry Mass spectroscopy Medical research Medicine Medicine and Health Sciences Membrane proteins Membranes Molecular modelling Mortality Neurology Neurosciences Occlusion Outer membrane proteins Peptides Protein expression Proteins Reperfusion Ribose Scientific imaging Stem cells Stroke Tagging Veins & arteries
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creator	Agarwal, Ank Park, Seongje Ha, Shinwon Kwon, Ji-Sun Khan, Mohammed Repon Kang, Bong Gu Dawson, Ted M Dawson, Valina L Andrabi, Shaida A Kang, Sung-Ung
description	Ischemic strokes result in the death of brain tissue and a wave of downstream effects, often leading to lifelong disabilities or death. However, the underlying mechanisms of ischemic damage and repair systems remain largely unknown. In order to better understand these mechanisms, TMT-isobaric mass tagging and mass spectrometry were conducted on brain cortex extracts from mice subjected to one hour of middle cerebral artery occlusion (MCAO) and after one hour of reperfusion. In total, 2,690 proteins were identified and quantified, out of which 65% of the top 5% of up- and down-regulated proteins were found to be significant (p < 0.05). Network-based gene ontology analysis was then utilized to cluster all identified proteins by protein functional groups and cellular roles. Although three different cellular functions were identified-organelle outer membrane proteins, cytosolic ribosome proteins, and spliceosome complex proteins-several functional domains were found to be common. Of these, organelle outer membrane proteins were downregulated whereas cytosolic ribosome and spliceosome complex proteins were upregulated, indicating that major molecular events post-stroke were translation-associated and subsequent signaling pathways (e.g., poly (ADP-ribose) (PAR) dependent cell death). By approaching stroke analyses via TMT-isobaric mass tagging, the work herein presents a grand scope of protein-based molecular mechanisms involved with ischemic stroke recovery.
doi_str_mv	10.1371/journal.pone.0231978
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This is an open access article distributed under the terms of the Creative Commons Attribution License: http://creativecommons.org/licenses/by/4.0/ (the “License”), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. 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subjects	Adenosine diphosphate Biology and Life Sciences Brain Brain research Cell death Cerebral blood flow Cerebral cortex Disabilities Engineering Functional groups Gene expression Ischemia Labeling Marking Mass spectrometry Mass spectroscopy Medical research Medicine Medicine and Health Sciences Membrane proteins Membranes Molecular modelling Mortality Neurology Neurosciences Occlusion Outer membrane proteins Peptides Protein expression Proteins Reperfusion Ribose Scientific imaging Stem cells Stroke Tagging Veins & arteries
title	Quantitative mass spectrometric analysis of the mouse cerebral cortex after ischemic stroke
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