From the ‡Neurovascular Research Laboratory, Vall d'Hebron Institute of Research (VHIR), Universitat Autònoma de Barcelona, Barcelona, Spain.
§Proteomics Core Facility, Faculty of medicine, University Medical Center, University of Geneva, Geneva, Switzerland.
Mol Cell Proteomics. 2018 Jan;17(1):175-189. doi: 10.1074/mcp.RA117.000419. Epub 2017 Nov 13.
Cerebral ischemia entails rapid tissue damage in the affected brain area causing devastating neurological dysfunction. How each component of the neurovascular unit contributes or responds to the ischemic insult in the context of the human brain has not been solved yet. Thus, the analysis of the proteome is a straightforward approach to unraveling these cell proteotypes. In this study, post-mortem brain slices from ischemic stroke patients were obtained corresponding to infarcted (IC) and contralateral (CL) areas. By means of laser microdissection, neurons and blood brain barrier structures (BBB) were isolated and analyzed using label-free quantification. MS data are available via ProteomeXchange with identifier PXD003519. Ninety proteins were identified only in neurons, 260 proteins only in the BBB and 261 proteins in both cell types. Bioinformatics analyses revealed that repair processes, mainly related to synaptic plasticity, are outlined in microdissected neurons, with nonexclusive important functions found in the BBB. A total of 30 proteins showing < 0.05 and fold-change> 2 between IC and CL areas were considered meaningful in this study: 13 in neurons, 14 in the BBB and 3 in both cell types. Twelve of these proteins were selected as candidates and analyzed by immunohistofluorescence in independent brains. The MS findings were completely verified for neuronal SAHH2 and SRSF1 whereas the presence in both cell types of GABT and EAA2 was only validated in neurons. In addition, SAHH2 showed its potential as a prognostic biomarker of neurological improvement when analyzed early in the plasma of ischemic stroke patients. Therefore, the quantitative proteomes of neurons and the BBB (or proteotypes) after human brain ischemia presented here contribute to increasing the knowledge regarding the molecular mechanisms of ischemic stroke pathology and highlight new proteins that might represent putative biomarkers of brain ischemia or therapeutic targets.
脑缺血导致受影响大脑区域的快速组织损伤,从而导致毁灭性的神经功能障碍。神经血管单元的每个组成部分如何在人类大脑的背景下对缺血性损伤做出贡献或做出反应,尚未得到解决。因此,分析蛋白质组是揭示这些细胞表型的直接方法。在这项研究中,从缺血性中风患者的死后脑切片中获得了与梗死(IC)和对侧(CL)区域相对应的脑切片。通过激光显微切割,分离神经元和血脑屏障结构(BBB),并使用无标记定量进行分析。MS 数据可通过 ProteomeXchange 以标识符 PXD003519 获得。仅在神经元中鉴定出 90 种蛋白质,仅在 BBB 中鉴定出 260 种蛋白质,在两种细胞类型中鉴定出 261 种蛋白质。生物信息学分析表明,修复过程主要与突触可塑性有关,在微切割神经元中得到了概述,在 BBB 中也发现了非排他性的重要功能。在 IC 和 CL 区域之间显示 <0.05 和 fold-change>2 的总共 30 种蛋白质被认为在本研究中具有意义:13 种在神经元中,14 种在 BBB 中,3 种在两种细胞类型中。其中 12 种蛋白质被选为候选物,并在独立的大脑中通过免疫荧光分析进行分析。MS 发现完全验证了神经元中的 SAHH2 和 SRSF1,而在两种细胞类型中存在的 GABT 和 EAA2 仅在神经元中得到验证。此外,当在缺血性中风患者的血浆中早期分析时,SAHH2 显示出作为神经功能改善的预后生物标志物的潜力。因此,这里呈现的人类脑缺血后神经元和 BBB 的定量蛋白质组(或蛋白质组型)有助于增加对缺血性中风病理分子机制的认识,并突出可能代表脑缺血或治疗靶点的新蛋白质。
