Department of Biomedical Engineering, College of Engineering, Boston University, Boston, Massachusetts; and Department of Health Sciences, Sargent College, Boston University, Boston, Massachusetts.
Department of Health Sciences, Sargent College, Boston University, Boston, Massachusetts.
Am J Physiol Heart Circ Physiol. 2014 Oct 15;307(8):H1252-61. doi: 10.1152/ajpheart.00392.2014. Epub 2014 Aug 15.
Increased aortic stiffness is an early and independent biomarker of cardiovascular disease. Here we tested the hypothesis that vascular smooth muscle cells (VSMCs) contribute significantly to aortic stiffness and investigated the mechanisms involved. The relative contributions of VSMCs, focal adhesions (FAs), and matrix to stiffness in mouse aorta preparations at optimal length and with confirmed VSMC viability were separated by the use of small-molecule inhibitors and activators. Using biomechanical methods designed for minimal perturbation of cellular function, we directly quantified changes with aging in aortic material stiffness. An alpha adrenoceptor agonist, in the presence of N(G)-nitro-l-arginine methyl ester (l-NAME) to remove interference of endothelial nitric oxide, increases stiffness by 90-200% from baseline in both young and old mice. Interestingly, increases are robustly suppressed by the Src kinase inhibitor PP2 in young but not old mice. Phosphotyrosine screening revealed, with aging, a biochemical signature of markedly impaired agonist-induced FA remodeling previously associated with Src signaling. Protein expression measurement confirmed a decrease in Src expression with aging. Thus we report here an additive model for the in vitro biomechanical components of the mouse aortic wall in which 1) VSMCs are a surprisingly large component of aortic stiffness at physiological lengths and 2) regulation of the VSMC component through FA signaling and hence plasticity is impaired with aging, diminishing the aorta's normal shock absorption function in response to stressors.
主动脉僵硬度增加是心血管疾病的早期和独立的生物标志物。在这里,我们检验了这样一个假设,即血管平滑肌细胞(VSMCs)对主动脉僵硬度有重要贡献,并研究了相关机制。在最佳长度下,使用小分子抑制剂和激活剂分离了 VSMCs、黏附斑(FAs)和基质对小鼠主动脉标本僵硬度的相对贡献,并且确认了 VSMC 的活力。使用设计用于最小化细胞功能干扰的生物力学方法,我们直接量化了与衰老相关的主动脉材料僵硬度的变化。在 N(G)-硝基-L-精氨酸甲酯(l-NAME)存在下,α肾上腺素能受体激动剂可增加基础值 90-200%的刚度,这种增加在年轻和老年小鼠中都存在。有趣的是,在年轻小鼠中,Src 激酶抑制剂 PP2 可显著抑制这种增加,但在老年小鼠中则不然。磷酸酪氨酸筛选显示,随着年龄的增长,FA 重塑的生化特征明显受损,这与以前与 Src 信号相关的激动剂诱导的 FA 重塑有关。蛋白质表达测量证实,随着年龄的增长,Src 的表达减少。因此,我们在这里报告了一个关于小鼠主动脉壁体外生物力学成分的附加模型,其中 1)VSMCs 是生理长度下主动脉僵硬度的一个惊人的大组成部分,2)通过 FA 信号调节 VSMC 成分,因此随着年龄的增长,可塑性受损,使主动脉对压力源的正常减震功能降低。