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细胞牵张增加髓袢升支粗段的超氧化物生成。

Cellular stretch increases superoxide production in the thick ascending limb.

作者信息

Garvin Jeffrey L, Hong Nancy J

机构信息

Hypertension and Vascular Research Division, Henry Ford Hospital, 2799 West Grand Boulevard, Detroit, MI 48202, USA.

出版信息

Hypertension. 2008 Feb;51(2):488-93. doi: 10.1161/HYPERTENSIONAHA.107.102228. Epub 2007 Dec 24.

DOI:10.1161/HYPERTENSIONAHA.107.102228
PMID:18158344
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2766239/
Abstract

Superoxide (O(2)(-)) is an important regulator of kidney function. We have recently shown that luminal flow stimulates O(2)(-) production in the thick ascending limb (TAL), attributable in part to mechanical factors. Stretch, pressure and shear stress all change when flow increases in the TAL. We hypothesized that stretch rather than shear stress or pressure per se stimulates O(2)(-) production by TALs. We measured O(2)(-) production in isolated perfused rat TALs using fluorescence microscopy and dihydroethidium. Tubules were perfused with a Na-free solution to eliminate the confounding effect of Na transport. Flow induced an increase in O(2)(-) production from 29+/-4 to 90+/-8 AU/s (P<0.002; n=5). The response to flow is rapidly reversible. O(2)(-) production by TALs perfused at 10 nL/min decreased from 113+/-6 to 25+/-10 AU/s (P<0.003; n=4) 15 minutes after flow was stopped. Increasing pressure and stretch in the absence of shear stress caused a significant increase in O(2)(-) production (40+/-6 to 118+/-17 AU/s; P<0.02; n=5). In contrast, eliminating shear stress had no effect (107+/-9 versus 108+/-10 AU/s; n=5). Increasing stretch by 27+/-2% in the presence of flow while reducing pressure stimulated O(2)(-) production from 66+/-7 to 84+/-9 AU/s (29+/-8%; P<0.02; n=5). Tempol inhibited this increase (n=5). We conclude that increasing stretch rather than pressure or shear stress accounts for the mechanical aspect of flow-induced O(2)(-) production in the TAL. Stretch of the TAL during hypertension, diabetes, and salt loading may contribute to renal damage.

摘要

超氧阴离子(O₂⁻)是肾功能的重要调节因子。我们最近发现,管腔流量可刺激髓袢升支粗段(TAL)产生O₂⁻,部分原因是机械因素。当TAL中的流量增加时,牵张、压力和剪切应力都会发生变化。我们推测,是牵张而非剪切应力或压力本身刺激TAL产生O₂⁻。我们使用荧光显微镜和二氢乙锭测量了分离灌注的大鼠TAL中的O₂⁻产生量。用无钠溶液灌注肾小管以消除钠转运的混杂效应。流量使O₂⁻产生量从29±4增加到90±8 AU/s(P<0.002;n = 5)。对流量的反应迅速可逆。停止流量15分钟后,以10灌注的TAL的O₂⁻产生量从113±6降至25±10 AU/s(P<0.003;n = 4)。在没有剪切应力的情况下增加压力和牵张会导致O₂⁻产生量显著增加(从40±6增加到118±17 AU/s;P<0.02;n = 5)。相比之下,消除剪切应力没有影响(107±9对108±10 AU/s;n = 5)。在有流量的情况下将牵张增加27±2%同时降低压力,可使O₂⁻产生量从66±7增加到84±9 AU/s(增加29±8%;P<0.02;n = 5)。Tempol抑制了这种增加(n = 5)。我们得出结论,在TAL中,流量诱导的O₂⁻产生的机械方面是由牵张增加而非压力或剪切应力引起的。高血压、糖尿病和盐负荷期间TAL的牵张可能导致肾损伤。

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