Revealing differences in the chemical form of zinc in brain tissue using K-edge X-ray absorption near-edge structure spectroscopy†

IF 2.9 3区 生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY Metallomics Pub Date : 2020-11-25 DOI:10.1039/D0MT00198H
Ashley L. Hollings, Virginie Lam, Ryu Takechi, John C. L. Mamo, Juliane Reinhardt, Martin D. de Jonge, Peter Kappen and Mark J. Hackett
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引用次数: 6

Abstract

Zinc is a prominent trace metal required for normal memory function. Memory loss and cognitive decline during natural ageing and neurodegenerative disease have been associated with altered brain-Zn homeostasis. Yet, the exact chemical pathways through which Zn influences memory function during health, natural ageing, or neurodegenerative disease remain unknown. The gap in the literature may in part be due to the difficulty to simultaneously image, and therefore, study the different chemical forms of Zn within the brain (or biological samples in general). To this extent, we have begun developing and optimising protocols that incorporate X-ray absorption near-edge structure (XANES) spectroscopic analysis of tissue at the Zn K-edge as an analytical tool to study Zn speciation in the brain. XANES is ideally suited for this task as all chemical forms of Zn are detected, the technique requires minimal sample preparation that may otherwise redistribute or alter the chemical form of Zn, and the Zn K-edge has known sensitivity to coordination geometry and ligand type. Herein, we report our initial results where we fit K-edge spectra collected from micro-dissected flash-frozen brain tissue, to a spectral library prepared from standard solutions, to demonstrate differences in the chemical form of Zn that exist between two brain regions, the hippocampus and cerebellum. Lastly, we have used an X-ray microprobe to demonstrate differences in Zn speciation within sub-regions of thin air-dried sections of the murine hippocampus; but, the corresponding results highlight that the chemical form of Zn is easily perturbed by sample preparation such as tissue sectioning or air-drying, which must be a critical consideration for future work.

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利用k边x射线吸收近边结构光谱法揭示脑组织中锌化学形态的差异
锌是一种重要的微量金属,需要正常的记忆功能。自然衰老和神经退行性疾病期间的记忆丧失和认知能力下降与脑锌稳态的改变有关。然而,锌在健康、自然衰老或神经退行性疾病期间影响记忆功能的确切化学途径仍不清楚。文献上的空白可能部分是由于难以同时成像,因此,研究大脑(或一般的生物样本)中锌的不同化学形式。在这种程度上,我们已经开始开发和优化方案,将组织的x射线吸收近边缘结构(XANES)光谱分析纳入Zn k边缘,作为研究Zn在大脑中形成的分析工具。XANES非常适合这项任务,因为可以检测到所有Zn的化学形式,该技术需要最少的样品制备,否则可能会重新分配或改变Zn的化学形式,并且Zn k -边缘对配位几何形状和配体类型具有已知的敏感性。在此,我们报告了我们的初步结果,我们将从显微解剖的快速冷冻脑组织收集的k边缘光谱与标准溶液制备的光谱库相匹配,以证明存在于两个大脑区域(海马和小脑)之间的锌化学形式的差异。最后,我们使用x射线微探针来证明小鼠海马薄风干切片亚区域内Zn物种形成的差异;但是,相应的结果强调,锌的化学形态很容易受到样品制备(如组织切片或风干)的干扰,这必须是未来工作的关键考虑因素。
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来源期刊
Metallomics
Metallomics 生物-生化与分子生物学
CiteScore
7.00
自引率
5.90%
发文量
87
审稿时长
1 months
期刊介绍: Global approaches to metals in the biosciences
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