Department of Surgery, Madigan Healthcare System, Joint Base Lewis-McChord, Tacoma, WA, USA.
J Vasc Surg. 2012 Apr;55(4):1096-1103.e51. doi: 10.1016/j.jvs.2011.08.060. Epub 2011 Nov 21.
Vascular endothelial cells serve as the first line of defense for end organs after ischemia and reperfusion injuries. The full etiology of this dysfunction is poorly understood, and valproic acid (VPA) has proven to be beneficial after traumatic injury. The purpose of this study was to determine the mechanism of action through which VPA exerts its beneficial effects.
Sixteen Yorkshire swine underwent a standardized protocol for an ischemia-reperfusion injury through hemorrhage and a supraceliac cross-clamp with ensuing 6-hour resuscitation. The experimental swine (n = 6), received VPA at cross-clamp application and were compared with a sham (n = 5) and injury-control models (n = 5). Aortic endothelium was harvested, and microarray analysis was performed along with a functional clustering analysis with gene transcript validation using relative quantitative polymerase chain reaction.
Clinical comparison of experimental swine matched for sex, weight, and length demonstrated that VPA significantly decreased resuscitative requirements, with improved hemodynamics and physiologic laboratory measurements. Six transcript profiles from the VPA treatment were compared with the 1536 gene transcripts (529 up and 1007 down) from sham and injury-control swine. Microarray analysis and a Database for Annotation, Visualization and Integrated Discovery functional pathway analysis approach identified biologic processes associated with pathologic vascular endothelial function, specifically through functional cluster pathways involving apoptosis/cell death and angiogenesis/vascular development, with five specific genes (THBS1, TNFRSF12A, ANGPTL4, RHOB, and RTN4) identified as members of both functional clusters. This study also examined gene expression of transforming growth factor (TGF)-β (TGF-β1, TGF-β2, and TGF-β-releasing thrombospondin 1 [THBS1]) and genes expressing vascular endothelial growth factor (VEGF) C, VEGFD, and VEGFR1 and found that these genes were involved in the endothelial functional preservation associated with VPA administration.
VPA minimized pathologic endothelial cell function through the TGF-β and VEGF functional pathways. This study also implicates that integrated functional modeling and analysis will enable advancements in endothelial dysfunction using a systems biology approach.
血管内皮细胞在缺血再灌注损伤后作为终末器官的第一道防线。这种功能障碍的确切病因尚不清楚,丙戊酸(VPA)已被证明在创伤后有益。本研究的目的是确定 VPA 发挥其有益作用的作用机制。
16 头约克夏猪经历了出血和腹主动脉上方夹闭的标准化缺血再灌注损伤方案,随后进行 6 小时复苏。实验猪(n=6)在夹闭时接受 VPA,并与假手术(n=5)和损伤对照模型(n=5)进行比较。采集主动脉内皮细胞,并进行微阵列分析,以及使用相对定量聚合酶链反应进行基因转录验证的功能聚类分析。
对性别、体重和长度匹配的实验猪进行临床比较表明,VPA 可显著减少复苏需求,改善血流动力学和生理实验室测量。将 VPA 治疗的 6 个转录谱与假手术和损伤对照猪的 1536 个基因转录本(529 个上调和 1007 个下调)进行比较。微阵列分析和数据库注释、可视化和综合发现功能途径分析方法确定了与病理性血管内皮功能相关的生物学过程,特别是通过涉及细胞凋亡/细胞死亡和血管生成/血管发育的功能聚类途径,有五个特定基因(THBS1、TNFRSF12A、ANGPTL4、RHOB 和 RTN4)被确定为两个功能群的成员。本研究还检查了转化生长因子(TGF)-β(TGF-β1、TGF-β2 和释放血栓调节蛋白 1[THBS1]的 TGF-β)和血管内皮生长因子(VEGF)C、VEGFD 和 VEGFR1 表达基因的基因表达,发现这些基因参与与 VPA 给药相关的内皮功能保存。
VPA 通过 TGF-β 和 VEGF 功能途径最小化病理性内皮细胞功能。本研究还表明,通过系统生物学方法,综合功能建模和分析将能够推进内皮功能障碍的研究。
