Department of Medicine of the Johns Hopkins School of Medicine, Baltimore, MD, USA.
J Vasc Surg. 2011 Oct;54(4):1117-1123.e1. doi: 10.1016/j.jvs.2011.04.037. Epub 2011 Jul 31.
Thrombosis is a major cause of the early failure of vein grafts (VGs) implanted during peripheral and coronary arterial bypass surgeries. Endothelial expression of thrombomodulin (TM), a key constituent of the protein C anticoagulant pathway, is markedly suppressed in VGs after implantation and contributes to local thrombus formation. While stretch-induced paracrine release of transforming growth factor-β (TGF-β) is known to negatively regulate TM expression in heart tissue, its role in regulating TM expression in VGs remains unknown.
Changes in relative mRNA expression of major TGF-β isoforms were measured by quantitative polymerase chain reaction (qPCR) in cultured human saphenous vein smooth muscle cells (HSVSMCs) subjected to cyclic stretch. To determine the effects of paracrine release of TGF-β on endothelial TM mRNA expression, human saphenous vein endothelial cells (HSVECs) were co-cultured with stretched HSVSMCs in the presence of 1D11, a pan-neutralizing TGF-β antibody, or 13C4, an isotype-control antibody. Groups of rabbits were then administered 1D11 or 13C4 and underwent interpositional grafting of jugular vein segments into the carotid circulation. The effect of TGF-β inhibition on TM gene expression was measured by qPCR; protein C activating capacity and local thrombus formation were measured by in situ chromogenic substrate assays; and VG remodeling was assessed by digital morphometry.
Cyclic stretch induced TGF-β(1) expression in HSVSMCs by 1.9 ± 0.2-fold (P < .001) without significant change in the expressions of TGF-β(2) and TGF-β(3). Paracrine release of TGF-β(1) by stretched HSVSMCs inhibited TM expression in stationary HSVECs placed in co-culture by 57 ± 12% (P = .03), an effect that was abolished in the presence of 1D11. Similarly, TGF-β(1) was the predominant isoform induced in rabbit VGs 7 days after implantation (3.5 ± 0.4-fold induction; P < .001). TGF-β(1) protein expression localized predominantly to the developing neointima and coincided with marked suppression of endothelial TM expression (16% ± 2% of vein controls; P < .03), a reduction in situ activated protein C (APC)-generating capacity (53% ± 9% of vein controls; P = .001) and increased local thrombus formation (3.7 ± 0.8-fold increase over vein controls; P < .01). External stenting of VGs to limit vessel distension significantly reduced TGF-β(1) induction and TM downregulation. Systemic administration of 1D11 also effectively prevented TM downregulation, preserved APC-generating capacity, and reduced local thrombus in rabbit VGs without observable effect on neointima formation and other morphometric parameters 6 weeks after implantation.
TM downregulation in VGs is mediated by paracrine release of TGF-β(1) caused by pressure-induced vessel stretch. Systemic administration of an anti-TGF-β antibody effectively prevented TM downregulation and preserved local thromboresistance without negative effect on VG remodeling.
血栓形成是外周和冠状动脉旁路手术中移植的静脉移植物(VG)早期失败的主要原因。移植后,血管内皮细胞表达的血栓调节蛋白(TM)明显受到抑制,这是导致局部血栓形成的原因之一。已知,伸展诱导的转化生长因子-β(TGF-β)旁分泌释放可负向调节心脏组织中的 TM 表达,但它在 VG 中的 TM 表达调节中的作用仍不清楚。
通过定量聚合酶链反应(qPCR)测量培养的人大隐静脉平滑肌细胞(HSVSMCs)在周期性拉伸下主要 TGF-β 同种型的相对 mRNA 表达的变化。为了确定 TGF-β 旁分泌释放对内皮 TM mRNA 表达的影响,将人大隐静脉内皮细胞(HSVECs)与伸展的 HSVSMCs 共培养,并在存在 1D11(一种泛中和 TGF-β 抗体)或 13C4(一种同种型对照抗体)的情况下进行。然后,给兔子分组并给予 1D11 或 13C4,并将颈静脉段植入颈动脉循环中进行间置移植。通过 qPCR 测量 TM 基因表达的抑制作用;通过原位显色底物测定测量蛋白 C 激活能力和局部血栓形成;通过数字形态计量学评估 VG 重塑。
周期性拉伸使 HSVSMCs 中的 TGF-β(1)表达增加了 1.9 ± 0.2 倍(P <.001),而 TGF-β(2)和 TGF-β(3)的表达没有明显变化。放置在共培养中的静止 HSVECs 中,伸展的 HSVSMCs 释放的 TGF-β(1)旁分泌抑制 TM 表达 57 ± 12%(P =.03),而在 1D11 存在的情况下则消除了这种抑制作用。同样,兔 VG 植入后 7 天,TGF-β(1)是诱导的主要同种型(诱导 3.5 ± 0.4 倍;P <.001)。TGF-β(1)蛋白表达主要定位于正在发育的新生内膜,同时内皮 TM 表达明显受到抑制(静脉对照的 16% ± 2%;P <.03),原位激活蛋白 C(APC)生成能力降低(静脉对照的 53% ± 9%;P =.001),局部血栓形成增加(静脉对照的 3.7 ± 0.8 倍增加;P <.01)。VG 的外部支架固定以限制血管扩张,可显著减少 TGF-β(1)诱导和 TM 下调。兔 VG 中系统给予 1D11 还可有效预防 TM 下调,维持 APC 生成能力,并减少局部血栓形成,而对植入后 6 周的新生内膜形成和其他形态计量学参数无明显影响。
VG 中的 TM 下调是由压力诱导的血管伸展引起的 TGF-β(1)旁分泌释放介导的。系统给予抗 TGF-β 抗体可有效预防 TM 下调并维持局部血栓抵抗力,而不会对 VG 重塑产生负面影响。
