Proteomics analysis of periplaque and chronic inactive multiple sclerosis lesions.

IF 3.5 3区 医学 Q2 NEUROSCIENCES Frontiers in Molecular Neuroscience Pub Date : 2024-08-21 eCollection Date: 2024-01-01 DOI:10.3389/fnmol.2024.1448215
Jordan M Wilkins, Kiran K Mangalaparthi, Brian C Netzel, William A Sherman, Yong Guo, Alicja Kalinowska-Lyszczarz, Akhilesh Pandey, Claudia F Lucchinetti
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Abstract

Background: Multiple sclerosis (MS) is a demyelinating disease of the central nervous system characterized by increased inflammation and immune responses, oxidative injury, mitochondrial dysfunction, and iron dyshomeostasis leading to demyelination and axonal damage. In MS, incomplete remyelination results in chronically demyelinated axons and degeneration coinciding with disability. This suggests a failure in the ability to remyelinate in MS, however, the precise underlying mechanisms remain unclear. We aimed to identify proteins whose expression was altered in chronic inactive white matter lesions and periplaque white matter in MS tissue to reveal potential pathophysiological mechanisms.

Methods: Laser capture microdissection coupled to proteomics was used to interrogate spatially altered changes in formalin-fixed paraffin-embedded brain tissue from three chronic MS individuals and three controls with no apparent neurological complications. Histopathological maps guided the capture of inactive lesions, periplaque white matter, and cortex from chronic MS individuals along with corresponding white matter and cortex from control tissue. Label free quantitation by liquid chromatography tandem mass spectrometry was used to discover differentially expressed proteins between the various brain regions.

Results: In addition to confirming loss of several myelin-associated proteins known to be affected in MS, proteomics analysis of chronic inactive MS lesions revealed alterations in myelin assembly, metabolism, and cytoskeletal organization. The top altered proteins in MS inactive lesions compared to control white matter consisted of PPP1R14A, ERMN, SIRT2, CARNS1, and MBLAC2.

Conclusion: Our findings highlight proteome changes in chronic inactive MS white matter lesions and periplaque white matter, which may be crucial for proper myelinogenesis, bioenergetics, focal adhesions, and cellular function. This study highlights the importance and feasibility of spatial approaches such as laser capture microdissection-based proteomics analysis of pathologically distinct regions of MS brain tissue. Identification of spatially resolved changes in the proteome of MS brain tissue should aid in the understanding of pathophysiological mechanisms and the development of novel therapies.

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斑块周围和慢性非活动性多发性硬化病变的蛋白质组学分析。
背景:多发性硬化症(MS)是一种中枢神经系统脱髓鞘疾病,其特点是炎症和免疫反应、氧化损伤、线粒体功能障碍和铁失衡导致脱髓鞘和轴突损伤。在多发性硬化症中,不完全的再髓鞘化导致轴突长期脱髓鞘和变性,并与残疾同时发生。这表明多发性硬化症患者的再髓鞘化能力失效,但其确切的内在机制仍不清楚。我们的目的是鉴定在多发性硬化症组织的慢性非活动性白质病变和斑块周围白质中表达发生改变的蛋白质,以揭示潜在的病理生理机制:方法:采用激光捕获显微切割和蛋白质组学相结合的方法,对来自三名慢性多发性硬化症患者和三名无明显神经系统并发症的对照组的福尔马林固定石蜡包埋脑组织的空间变化进行检测。组织病理学图引导捕获慢性多发性硬化症患者的非活动性病变、斑周白质和皮质,以及对照组组织中的相应白质和皮质。采用液相色谱串联质谱法进行无标记定量,以发现不同脑区之间表达不同的蛋白质:结果:除了证实了多发性硬化症中已知的几种髓鞘相关蛋白的缺失外,慢性非活动性多发性硬化症病变的蛋白质组学分析还揭示了髓鞘组装、代谢和细胞骨架组织的改变。与对照组白质相比,多发性硬化症非活动性病变中改变最大的蛋白质包括PPP1R14A、ERMN、SIRT2、CARNS1和MBLAC2:我们的研究结果突显了慢性非活动性多发性硬化症白质病变和斑块周围白质中蛋白质组的变化,这些变化可能对正常的髓鞘生成、生物能、病灶粘附和细胞功能至关重要。这项研究强调了空间方法的重要性和可行性,如基于激光捕获显微切割的蛋白质组学分析,对多发性硬化症脑组织的不同病理区域进行分析。确定多发性硬化症脑组织蛋白质组的空间分辨变化有助于了解病理生理机制和开发新型疗法。
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来源期刊
CiteScore
5.70
自引率
2.10%
发文量
669
审稿时长
14 weeks
期刊介绍: Frontiers in Molecular Neuroscience is a first-tier electronic journal devoted to identifying key molecules, as well as their functions and interactions, that underlie the structure, design and function of the brain across all levels. The scope of our journal encompasses synaptic and cellular proteins, coding and non-coding RNA, and molecular mechanisms regulating cellular and dendritic RNA translation. In recent years, a plethora of new cellular and synaptic players have been identified from reduced systems, such as neuronal cultures, but the relevance of these molecules in terms of cellular and synaptic function and plasticity in the living brain and its circuits has not been validated. The effects of spine growth and density observed using gene products identified from in vitro work are frequently not reproduced in vivo. Our journal is particularly interested in studies on genetically engineered model organisms (C. elegans, Drosophila, mouse), in which alterations in key molecules underlying cellular and synaptic function and plasticity produce defined anatomical, physiological and behavioral changes. In the mouse, genetic alterations limited to particular neural circuits (olfactory bulb, motor cortex, cortical layers, hippocampal subfields, cerebellum), preferably regulated in time and on demand, are of special interest, as they sidestep potential compensatory developmental effects.
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