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肺组织中核因子-κB激活的成熟差异及其在高氧耐受性中的作用

Maturational differences in lung NF-kappaB activation and their role in tolerance to hyperoxia.

作者信息

Yang Guang, Abate Aida, George Adia G, Weng Yi-Hao, Dennery Phyllis A

机构信息

Division of Neonatology, Children's Hospital of Philadelphia, Philadelphia, Pennsylvania, USA.

出版信息

J Clin Invest. 2004 Sep;114(5):669-78. doi: 10.1172/JCI19300.

DOI:10.1172/JCI19300
PMID:15343385
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC514581/
Abstract

Neonatal rodents are more tolerant to hyperoxia than adults. We determined whether maturational differences in lung NF-kappaB activation could account for the differences. After hyperoxic exposure (O2 > 95%), neonatal (<12 hours old) lung NF-kappaB binding was increased and reached a maximum between 8 and 16 hours, whereas in adults no changes were observed. Additionally, neonatal NF-kappaB/luciferase transgenic mice (incorporating 2 NF-kappaB consensus sequences driving luciferase gene expression) demonstrated enhanced in vivo NF-kappaB activation after hyperoxia in real time. In the lungs of neonates, there was a propensity toward NF-kappaB activation as evidenced by increased lung I-kappaB kinase protein levels, I-kappaBalpha phosphorylation, beta-transducin repeat-containing protein levels, and total I-kappaBalpha degradation. Increased lung p-JNK immunoreactive protein was observed only in the adult lung. Inhibition of pI-kappaBalpha by BAY 11-7085 resulted in decreased Bcl-2 protein levels in neonatal lung homogenates and decreased cell viability in lung primary cultures after hyperoxic exposure. Furthermore, neonatal p50-null mutant (p50(-/-)) mice showed increased lung DNA degradation and decreased survival in hyperoxia compared with WT mice. These data demonstrate that there are maturational differences in lung NF-kappaB activation and that enhanced NF-kappaB may serve to protect the neonatal lung from acute hyperoxic injury via inhibition of apoptosis.

摘要

新生啮齿动物比成年动物对高氧更具耐受性。我们确定了肺中NF-κB激活的成熟差异是否可以解释这些差异。在高氧暴露(氧气>95%)后,新生(<12小时龄)肺NF-κB结合增加,并在8至16小时达到最大值,而在成年动物中未观察到变化。此外,新生NF-κB/荧光素酶转基因小鼠(包含驱动荧光素酶基因表达的2个NF-κB共有序列)在高氧后实时显示体内NF-κB激活增强。在新生动物的肺中,存在NF-κB激活的倾向,表现为肺I-κB激酶蛋白水平增加、I-κBα磷酸化、含β-转导蛋白重复序列的蛋白水平增加以及总I-κBα降解。仅在成年动物肺中观察到肺p-JNK免疫反应性蛋白增加。用BAY 11-7085抑制pI-κBα导致新生动物肺匀浆中Bcl-2蛋白水平降低,并在高氧暴露后肺原代培养物中细胞活力降低。此外,与野生型小鼠相比,新生p50基因敲除突变体(p50(-/-))小鼠在高氧时肺DNA降解增加且存活率降低。这些数据表明肺NF-κB激活存在成熟差异,增强的NF-κB可能通过抑制凋亡来保护新生动物肺免受急性高氧损伤。

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