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斑马鱼钝性颅脑损伤会引发异质性损伤病理,模拟人类颅脑损伤,并通过整个神经轴上依赖于音猬因子的细胞增殖做出反应。

Zebrafish Blunt-Force TBI Induces Heterogenous Injury Pathologies That Mimic Human TBI and Responds with Sonic Hedgehog-Dependent Cell Proliferation across the Neuroaxis.

作者信息

Hentig James, Cloghessy Kaylee, Lahne Manuela, Jung Yoo Jin, Petersen Rebecca A, Morris Ann C, Hyde David R

机构信息

Department of Biological Sciences, University of Notre Dame, South Bend, IN 46556, USA.

Center for Zebrafish Research, University of Notre Dame, South Bend, IN 46556, USA.

出版信息

Biomedicines. 2021 Jul 22;9(8):861. doi: 10.3390/biomedicines9080861.

DOI:10.3390/biomedicines9080861
PMID:34440066
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8389629/
Abstract

Blunt-force traumatic brain injury (TBI) affects an increasing number of people worldwide as the range of injury severity and heterogeneity of injury pathologies have been recognized. Most current damage models utilize non-regenerative organisms, less common TBI mechanisms (penetrating, chemical, blast), and are limited in scalability of injury severity. We describe a scalable blunt-force TBI model that exhibits a wide range of human clinical pathologies and allows for the study of both injury pathology/progression and mechanisms of regenerative recovery. We modified the Marmarou weight drop model for adult zebrafish, which delivers a scalable injury spanning mild, moderate, and severe phenotypes. Following injury, zebrafish display a wide range of severity-dependent, injury-induced pathologies, including seizures, blood-brain barrier disruption, neuroinflammation, edema, vascular injury, decreased recovery rate, neuronal cell death, sensorimotor difficulties, and cognitive deficits. Injury-induced pathologies rapidly dissipate 4-7 days post-injury as robust cell proliferation is observed across the neuroaxis. In the cerebellum, proliferating :GFP-positive cells originated from the cerebellar crest by 60 h post-injury, which then infiltrated into the granule cell layer and differentiated into neurons. Shh pathway genes increased in expression shortly following injury. Injection of the Shh agonist purmorphamine in undamaged fish induced a significant proliferative response, while the proliferative response was inhibited in injured fish treated with cyclopamine, a Shh antagonist. Collectively, these data demonstrate that a scalable blunt-force TBI to adult zebrafish results in many pathologies similar to human TBI, followed by recovery, and neuronal regeneration in a Shh-dependent manner.

摘要

随着人们认识到钝性创伤性脑损伤(TBI)的损伤严重程度范围和损伤病理的异质性,全球范围内受其影响的人数正在增加。目前大多数损伤模型使用非再生生物、不太常见的TBI机制(穿透性、化学性、爆炸性),并且在损伤严重程度的可扩展性方面存在局限。我们描述了一种可扩展的钝性创伤性脑损伤模型,该模型展现出广泛的人类临床病理特征,并允许对损伤病理/进展以及再生恢复机制进行研究。我们对成年斑马鱼的 Marmarou 重物坠落模型进行了改进,该模型可产生涵盖轻度、中度和重度表型的可扩展损伤。损伤后,斑马鱼表现出广泛的严重程度依赖性、损伤诱导的病理特征,包括癫痫发作、血脑屏障破坏、神经炎症、水肿、血管损伤、恢复率降低、神经元细胞死亡、感觉运动障碍和认知缺陷。损伤诱导的病理特征在损伤后4 - 7天迅速消散,因为在整个神经轴上观察到强大的细胞增殖。在小脑中,损伤后60小时,增殖的绿色荧光蛋白(GFP)阳性细胞起源于小脑嵴,然后浸润到颗粒细胞层并分化为神经元。Sonic Hedgehog(Shh)信号通路基因在损伤后不久表达增加。在未受损的鱼中注射Shh激动剂嘌呤胺会诱导显著的增殖反应,而在用Shh拮抗剂环杷明处理的受伤鱼中,增殖反应受到抑制。总体而言,这些数据表明,对成年斑马鱼进行可扩展的钝性创伤性脑损伤会导致许多与人类TBI相似的病理特征,随后是恢复,并且以依赖Shh的方式进行神经元再生。

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