Zacharek Alex, Chen Jieli, Cui Xu, Yang Yuping, Chopp Michael
Neurology Research, E&R Building, Room #3091, Henry Ford Hospital, 2799 West Grand Boulevard, Detroit, MI 48202, USA.
Stroke. 2009 Jan;40(1):254-60. doi: 10.1161/STROKEAHA.108.524116. Epub 2008 Oct 16.
Notch signaling activity regulates arteriogenesis. Presenilin 1 (PS1) mediates Notch signaling activity via cleavage of Notch, liberating Notch intracellular domain (NICD). We tested the hypothesis that simvastatin enhances arteriogenesis after stroke by increasing PS1 activation of the Notch signaling pathway.
Rats were subjected to middle cerebral artery occlusion (MCAo) and treated with or without simvastatin (1 mg/kg) starting 24 hours after stroke and daily for 7 days; they were euthanized 14 days after stroke. Immunostaining, Western blot, and real-time polymerase chain reaction assays were performed.
Simvastatin significantly increased arterial diameter, density, and vascular smooth muscle cell proliferation, and upregulated PS1, Notch1, and NICD expression in the ischemic border tissue and in the cerebral arteries compared with MCAo control rats, respectively. However, simvastatin did not increase arteriogenesis, PS1, and NICD expression in sham control animals. To investigate the mechanisms of simvastatin-induced arteriogenesis, primary cerebral artery cultures were used. Rats were subjected to MCAo and treated with or without simvastatin daily for 7 days. The cerebral arteries derived from these stroke rats were cultured in matrigel and treated with or without a gamma40-secretase inhibitor II, which blocks Notch signaling activity, inhibiting NICD production. Arterial cell migration was measured. simvastatin treatment significantly increased arterial cell migration compared to control MCAo artery, whereas inhibition of Notch signaling activity by the gamma40-secretase inhibitor II significantly attenuated simvastatin-induced arterial cell migration.
These data indicate that simvastatin increases arteriogenesis after stroke, and that simvastatin upregulation of PS1 expression and Notch signaling activity may facilitate an increase in arteriogenesis.
Notch信号通路活性调节动脉生成。早老素1(PS1)通过切割Notch介导Notch信号通路活性,释放Notch细胞内结构域(NICD)。我们检验了如下假设:辛伐他汀通过增加Notch信号通路的PS1激活来增强中风后的动脉生成。
对大鼠进行大脑中动脉闭塞(MCAo),并在中风后24小时开始给予或不给予辛伐他汀(1mg/kg)治疗,每日给药,持续7天;在中风后14天对大鼠实施安乐死。进行免疫染色、蛋白质印迹法和实时聚合酶链反应分析。
与MCAo对照大鼠相比,辛伐他汀显著增加了缺血边缘组织和脑动脉的动脉直径、密度以及血管平滑肌细胞增殖,并上调了PS1、Notch1和NICD的表达。然而,辛伐他汀并未增加假手术对照动物的动脉生成、PS1和NICD表达。为研究辛伐他汀诱导动脉生成的机制,使用了原代脑动脉培养物。对大鼠进行MCAo,并每日给予或不给予辛伐他汀治疗,持续7天。将这些中风大鼠的脑动脉在基质胶中培养,并给予或不给予γ40-分泌酶抑制剂II(其可阻断Notch信号通路活性,抑制NICD产生)处理。测量动脉细胞迁移情况。与对照MCAo动脉相比,辛伐他汀治疗显著增加了动脉细胞迁移,而γ40-分泌酶抑制剂II对Notch信号通路活性的抑制显著减弱了辛伐他汀诱导的动脉细胞迁移。
这些数据表明,辛伐他汀可增加中风后的动脉生成,且辛伐他汀上调PS1表达和Notch信号通路活性可能有助于动脉生成增加。