Hao Zhifang, Jiang Xi, Sharafeih Roshanak, Shen Shujing, Hand Arthur R, Cone Robert E, O'Rourke James
Department of Pathology, University of Connecticut Health Center, Farmington 06030-3105, USA.
Stress. 2005 Jun;8(2):141-9. doi: 10.1080/10253890500168098.
Recurrent stress is clinically associated with early onset hypertension and coronary artery disease. A mechanism linking emotion to pathogenic remodeling of the artery wall has not been identified. Stress stimulates acute regulated release of tissue plasminogen activator (t-PA) into the circulation, which is presently attributed to the vascular endothelium. Sympathetic neurons also synthesize t-PA and axonally transport it to the arterial smooth muscle. Unlike release by the endothelium, a stress-stimulated sympathetic discharge would potentially accelerate degradation of the wall matrix by plasmin. To assess whether sympathetic axons are the principal source of acute stress-induced arterial release of t-PA, we compared the output from small densely innervated and large sparsely innervated isolated artery segments before and after sympathetic stimulation, and after ablations. Following phenylephrine infusion densely-innervated microvessels in uveal eyecups were released over 60-fold greater amounts of active t-PA per milligram than the sparsely innervated aorta; and ten-fold more than carotid artery segments. Mesenteric artery release was 4.8-fold greater than release by the carotid artery. In vivo, uveal release of t-PA increased more than three-fold within one minute following superior cervical sympathetic ganglion electrical stimulation, and after phenylephrine, or nicotine infusions of the anterior chamber. Circulating levels of t-PA fell 70% following chemical sympathectomy. We propose that sympathetic nerves are the primary source of stress-induced release of t-PA into and from the densely innervated resistance arteries and arterioles, where dysregulated plasmin-induced proteolysis could damage the wall matrix.
反复应激在临床上与早发性高血压和冠状动脉疾病相关。尚未确定将情绪与动脉壁致病性重塑联系起来的机制。应激刺激组织纤溶酶原激活物(t-PA)急性调节性释放到循环中,目前认为这归因于血管内皮。交感神经元也合成t-PA并通过轴突将其运输到动脉平滑肌。与内皮释放不同,应激刺激的交感神经放电可能会加速纤溶酶对壁基质的降解。为了评估交感神经轴突是否是急性应激诱导动脉释放t-PA的主要来源,我们比较了交感神经刺激前后以及消融后,小的密集神经支配和大的稀疏神经支配的离体动脉段的输出。在注入去氧肾上腺素后,葡萄膜眼杯中小的密集神经支配的微血管每毫克释放的活性t-PA比稀疏神经支配的主动脉多60倍以上;比颈动脉段多10倍。肠系膜动脉的释放比颈动脉的释放大4.8倍。在体内,颈上交感神经节电刺激、前房注入去氧肾上腺素或尼古丁后一分钟内,葡萄膜t-PA的释放增加了三倍多。化学交感神经切除术后,循环中的t-PA水平下降了70%。我们提出,交感神经是应激诱导t-PA释放到密集神经支配的阻力动脉和小动脉以及从这些部位释放t-PA的主要来源,在这些部位,纤溶酶诱导的蛋白水解失调可能会损害壁基质。