Grabowski E F, Jaffe E A, Weksler B B
J Lab Clin Med. 1985 Jan;105(1):36-43.
While fluid shear stress is an important cardiovascular factor in vivo, it has generally been ignored in in vitro assays of endothelial cell function. We quantified the influence of shear stress on the production of prostacyclin by confluent monolayers of bovine aortic endothelial cells placed in a lucite flow chamber and exposed to flowing culture medium at constant shear stress at 37 degrees C and pH 7.4. Continuous inverted-phase microscopy (x 300) of the monolayers showed no significant contraction or detachment of cells under these conditions. Step increases in shear stress from zero to 14 dyne/cm2 caused rapid rises in prostacyclin production, from a baseline (n = 4) of 0.17 +/- 0.062 ng/cm2.min (mean +/- SEM) to peak values within 2 minutes, followed by a decline over several minutes. Peak prostacyclin production increased (p less than 0.005) with shear stress, from 0.60 +/- 0.13 ng/cm2.min at 0.9 dyne/cm2 (n = 14) to 2.33 +/- 0.67 ng/cm2.min at 14 dyne/cm2 (n = 10). The time integral of production or total production, however, did not significantly change with shear stress at least for shear stresses above 0.9 dyne/cm2. Once stressed, cell monolayers produced additional prostacyclin in response to stimulation by Na arachidonate or the calcium ionophore A23187, but not to repeat mechanical stimulation. We conclude that endothelial cells produce bursts of prostacyclin in response to suddenly imposed arterial-like shear stress, and that the peak rate, but not the time integral, of this production increases with shear stress.
虽然流体剪切应力是体内一个重要的心血管因素,但在体外内皮细胞功能测定中通常被忽视。我们对置于有机玻璃流动腔中的牛主动脉内皮细胞汇合单层施加37℃、pH 7.4的恒定剪切应力,并使其暴露于流动的培养基中,以此来量化剪切应力对前列环素产生的影响。在这些条件下,对单层细胞进行连续的倒置相差显微镜观察(放大300倍),结果显示细胞无明显收缩或脱离。剪切应力从零突然增加到14达因/平方厘米会导致前列环素产量迅速上升,从基线水平(n = 4)的0.17±0.062纳克/平方厘米·分钟(平均值±标准误)在2分钟内升至峰值,随后在几分钟内下降。前列环素的峰值产量随剪切应力增加(p<0.005),从0.9达因/平方厘米时的0.60±0.13纳克/平方厘米·分钟(n = 14)升至14达因/平方厘米时的2.33±0.67纳克/平方厘米·分钟(n = 10)。然而,至少对于高于0.9达因/平方厘米的剪切应力,产量的时间积分或总产量并未随剪切应力显著变化。一旦受到应力作用,细胞单层会对花生四烯酸钠或钙离子载体A23187的刺激产生额外的前列环素,但对重复的机械刺激无反应。我们得出结论,内皮细胞会对突然施加的类似动脉的剪切应力产生前列环素的爆发性分泌,并且这种分泌的峰值速率而非时间积分会随剪切应力增加。
