Dept. of Nephrology and Hypertension, University Medical Center, Utrecht, The Netherlands.
Am J Physiol Endocrinol Metab. 2011 Apr;300(4):E691-8. doi: 10.1152/ajpendo.00710.2010. Epub 2011 Jan 25.
We hypothesized that perinatal inhibition of soluble epoxide hydrolase (SEH), which metabolizes epoxyeicosatrienoic acids in the arachidonic acid (AA) cascade, with an orally active SEH inhibitor, 12-(3-adamantan-1-yl-ureido)-dodecanoic acid (AUDA), would persistently reduce blood pressure (BP) in adult SHR despite discontinuation of AUDA at 4 wk of age. Renal cytoplasmic epoxide hydrolase-2 (Ephx2) gene expression was enhanced in SHR vs. WKY from 2 days to 24 wk. Effects of perinatal treatment with AUDA, supplied to SHR dams until 4 wk after birth, on BP in female and male offspring and renal oxylipin metabolome in female offspring were observed and contrasted to female SHR for direct effects of AUDA (8-12 wk). Briefly, inhibition of SEH was effective in persistently reducing BP in female SHR when applied during the perinatal phase. This was accompanied by marked increases in major renal AA epoxides and decreases in renal lipoxygenase products of AA. Early inhibition of SEH induced a delayed increase in renal 5-HETE at 24 wk, in contrast to a decrease at 2 wk. Inhibition of SEH in female SHR from 8 to 12 wk did not reduce BP but caused profound decreases in renal 15(S)-HETrE, LTB4, TBX2, 5-HETE, and 20-HETE and increases in TriHOMEs. In male SHR, BP reduction after perinatal AUDA was transient. Thus, Ephx2 transcription and SEH activity in early life may initiate mechanisms that eventually contribute to high BP in adult female SHR. However, programmed BP-lowering effects of perinatal SEH inhibition in female SHR cannot be simply explained by persistent reduction in renal SEH activity but rather by more complex and temporally dynamic interactions between the renal SEH, lipoxygenase, and cyclooxygenase pathways.
我们假设,通过口服活性 SEH 抑制剂 12-(3-金刚烷-1-基-脲基)-十二烷酸 (AUDA) 抑制围产期可溶性环氧化物水解酶 (SEH),后者代谢花生四烯酸 (AA) 级联中的环氧化物水解酶,会持续降低成年 SHR 的血压 (BP),尽管在 4 周龄时停止 AUDA。与 WKY 相比,SHR 从 2 天到 24 周时肾细胞质环氧化物水解酶-2 (Ephx2) 基因表达增强。观察并对比了围产期 AUDA 处理 (在出生后 4 周前供应给 SHR 母鼠) 对雌性和雄性后代 BP 以及雌性后代肾氧化应激代谢组的影响,并与直接接受 AUDA 处理的雌性 SHR 进行了对比 (8-12 周)。简要地说,在围产期应用 SEH 抑制剂可有效持续降低雌性 SHR 的 BP。这伴随着肾 AA 主要环氧化物的显著增加和肾 AA 脂氧合酶产物的减少。与 2 周时的减少相反,早期抑制 SEH 会导致 24 周时肾 5-HETE 的延迟增加。在 8 至 12 周时抑制雌性 SHR 的 SEH 不会降低 BP,但会导致肾 15(S)-HETrE、LTB4、TBX2、5-HETE 和 20-HETE 显著减少,TriHOMEs 增加。在雄性 SHR 中,围产期 AUDA 后的 BP 降低是短暂的。因此,Ephx2 转录和生命早期的 SEH 活性可能启动了最终导致成年雌性 SHR 高血压的机制。然而,围产期 SEH 抑制对雌性 SHR 的编程性降压作用不能简单地解释为肾 SEH 活性的持续降低,而是肾 SEH、脂氧合酶和环氧化酶途径之间更复杂和随时间变化的相互作用。