关键的 microRNA 在调节氧化应激期间鼠肺泡上皮细胞粒细胞巨噬细胞集落刺激因子表达中的作用。

Key role of microRNA in the regulation of granulocyte macrophage colony-stimulating factor expression in murine alveolar epithelial cells during oxidative stress.

机构信息

From the Department of Veterans Affairs Medical Center, Salt Lake City, Utah 84148 and.

出版信息

J Biol Chem. 2014 Feb 14;289(7):4095-105. doi: 10.1074/jbc.M113.535922. Epub 2013 Dec 26.

DOI:10.1074/jbc.M113.535922

PMID:24371146

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3924275/

Abstract

GM-CSF is an endogenous pulmonary cytokine produced by normal alveolar epithelial cells (AEC) that is a key defender of the alveolar space. AEC GM-CSF expression is suppressed by oxidative stress through alternations in mRNA turnover, an effect that is reversed by treatment with recombinant GM-CSF. We hypothesized that specific microRNA (miRNA) would play a key role in AEC GM-CSF regulation. A genome-wide miRNA microarray identified 19 candidate miRNA altered in primary AEC during oxidative stress with reversal by treatment with GM-CSF. Three of these miRNA (miR 133a, miR 133a*, and miR 133b) are also predicted to bind the GM-CSF 3'-untranslated region (UTR). PCR for the mature miRNA confirmed induction during oxidative stress that was reversed by treatment with GM-CSF. Experiments using a GM-CSF 3'-UTR reporter construct demonstrated that miR133a and miR133b effects on GM-CSF expression are through interactions with the GM-CSF 3'-UTR. Using lentiviral transduction of specific mimics and inhibitors in primary murine AEC, we determined that miR133a and miR133b suppress GM-CSF expression and that their inhibition both reverses oxidant-induced suppression of GM-CSF expression and increases basal expression of GM-CSF in cells in normoxia. In contrast, these miRNAs are not active in regulation of GM-CSF expression in murine EL4 T cells. Thus, members of the miR133 family play key roles in regulation of GM-CSF expression through effects on mRNA turnover in AEC during oxidative stress. Increased understanding of GM-CSF gene regulation may provide novel miRNA-based interventions to augment pulmonary innate immune defense in lung injury.

摘要

GM-CSF 是一种内源性的肺细胞因子，由正常肺泡上皮细胞（AEC）产生，是肺泡空间的主要防御者。AEC GM-CSF 的表达受到氧化应激的抑制，这种抑制是通过 mRNA 周转率的改变来实现的，而这种作用可以通过重组 GM-CSF 治疗来逆转。我们假设特定的 microRNA（miRNA）将在 AEC GM-CSF 调节中发挥关键作用。全基因组 miRNA 微阵列鉴定出在氧化应激过程中，原代 AEC 中 19 种候选 miRNA 发生改变，用 GM-CSF 治疗可逆转这一变化。其中 3 种 miRNA（miR 133a、miR 133a* 和 miR 133b）也被预测与 GM-CSF 3'-UTR 结合。成熟 miRNA 的 PCR 证实了在氧化应激过程中的诱导作用，这种诱导作用可以被 GM-CSF 治疗逆转。使用 GM-CSF 3'-UTR 报告基因构建体的实验表明，miR133a 和 miR133b 对 GM-CSF 表达的影响是通过与 GM-CSF 3'-UTR 的相互作用实现的。在原代小鼠 AEC 中使用特定的模拟物和抑制剂的慢病毒转导，我们确定 miR133a 和 miR133b 抑制 GM-CSF 的表达，并且它们的抑制作用既可以逆转氧化剂诱导的 GM-CSF 表达抑制，又可以增加正常氧条件下细胞中 GM-CSF 的基础表达。相比之下，这些 miRNA 在调节鼠 EL4 T 细胞中的 GM-CSF 表达中不起作用。因此，miR133 家族成员在氧化应激期间通过影响 AEC 中的 mRNA 周转率来发挥关键作用，调节 GM-CSF 的表达。对 GM-CSF 基因调控的深入了解可能为增强肺部先天免疫防御提供新的基于 miRNA 的干预措施，以减轻肺部损伤。

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