From the Department of Veterans Affairs Medical Center, Salt Lake City, Utah 84148 and.
J Biol Chem. 2014 Feb 14;289(7):4095-105. doi: 10.1074/jbc.M113.535922. Epub 2013 Dec 26.
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.
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。
