单次和重复缺氧条件对大脑微血管转录的差异调节。

Conditioning medicine Pub Date : 2021-01-01
Jarrod C Harman, David A Otohinoyi, John W Reitnauer, Ann M Stowe, Jeff M Gidday
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引用次数: 0

摘要

全身调节疗法在所有组织层面上提供脑保护,对神经元、神经胶质、血管平滑肌和内皮细胞自主发生,它们是适应性和先天免疫系统的系统性中介。本研究旨在检测小鼠大脑微血管在单次缺氧条件(HX1)和重复缺氧条件(HX9)后的急性(3小时)和延迟(2天)基因表达变化,我们之前已经证明后者可以将局灶性卒中耐受性从几天延长到几个月。Microarray (Illumina)分析了以下五组成年小鼠大脑的微血管富集部分(naïve;HX1-3h;HX1-2days;HX9-3h;HX9-2days)。使用Ingenuity Pathway Analysis软件对差异表达基因进行生物信息学分析,并使用qPCR验证选择的上调和下调基因。正如预期的那样,一些差异表达基因在多个治疗或时间点上是共同的,而另一些差异表达基因在治疗或时间点上是独特的。生物信息学分析提供了对急性(3h)炎症和免疫信号通路的见解,这些信号通路可能被HX1和HX9不同地激活,抗炎和营养通路与HX1后两天的耐缺血表型一致。有趣的是,在HX9后两天,微血管转录沉默,相对于naïve小鼠,只有五个基因保持差异表达。我们的微阵列研究结果和生物信息学分析表明,hx9处理小鼠的大脑微血管表现出免疫系统信号的早期激活,而这在hx9处理小鼠的微血管中很大程度上被抑制。这些反应之间的这些差异和其他差异需要进一步研究,包括在蛋白质组学水平上,并通过药理学和遗传学实验来揭示因果关系,以进一步了解持久卒中耐受性的机制。
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Differential regulation of cerebral microvascular transcription by single and repetitive hypoxic conditioning.

Systemic conditioning therapeutics afford brain protection at all levels of organization, occurring autonomously for neurons, glia, vascular smooth muscle, and endothelium, which are mediated systemically for the adaptive and innate immune system. The present study was undertaken to examine acute (3 h) and delayed (2 days) gene expression changes in mouse cerebral microvessels following single hypoxic conditioning (HX1) and repetitive hypoxic conditioning (HX9), the latter for which we showed previously to extend focal stroke tolerance from days to months. Microarray (Illumina) analyses were performed on microvessel-enriched fractions of adult mouse brain obtained from the following five groups (naïve; HX1-3h; HX1-2days; HX9-3h; HX9-2days). Differentially expressed genes were analyzed bioinformatically using Ingenuity Pathway Analysis software, with qPCR validating selected up- and down-regulated genes. As expected, some differentially expressed genes were common to more than one treatment or time point, whereas others were unique to treatment or time point. Bioinformatic analyses provided insights into acute (3h) inflammatory and immune signaling pathways that may be differentially activated by HX1 and HX9, with anti-inflammatory and trophic pathways coincident with the ischemia-tolerant phenotype two days after HX1. Interestingly, two days after HX9, microvessels were transcriptionally silent, with only five genes remaining differentially expressed relative to naïve mice. Our microarray findings and bioinformatic analyses suggest that cerebral microvessels from HX1-treated mice exhibit early activation of immune system signaling that is largely suppressed in microvessels from HX9-treated mice. These and other differences between these responses require further study, including at the proteomic level, and with pharmacologic and genetic experiments designed to reveal causality, to reveal further insights into the mechanisms underlying long-lasting stroke tolerance.

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