Nitric oxide synthase phosphorylation in fetoplacental endothelium is enhanced by agonism of Piezo1 mechanosensor in small for gestational age babies.

L C Morley, M Debant, H J Gaunt, N A B Simpson, D J Beech
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Abstract

Lay summary: Friction caused by blood flowing across cells that line blood vessels (endothelial cells) activates sensors of mechanical force. This produces nitric oxide (NO) which widens placental blood vessels, enabling more blood flow to the baby. This study sought to determine whether the mechanical sensor, Piezo1, is important for NO production in fetoplacental endothelial cells (FpECs) and whether the steps in this pathway are different in small for gestational age (SGA) babies, where placental blood flow is often altered. We showed that in healthy FpECs, blood flow increased NO signalling. We suggest that in SGA babies, FpECs have an increase in baseline levels of NO signalling, suggestive of a compensatory drive. Treating healthy and SGA cells with a Piezo1 chemical activator, Yoda1, upregulated NO signalling. This shows that Piezo1 is linked to NO and that in SGA, FpECs have the capacity to further increase NO. Further research will establish whether Piezo1 enhancement leads to increased blood flow in the placenta. If so, Piezo1 could be a new target for developing treatments to prevent poor growth of babies in the womb.

Abstract Image

Abstract Image

胎龄小的胎胎盘内皮一氧化氮合酶磷酸化被Piezo1机械传感器的激动作用增强。
摘要:血液流经血管细胞(内皮细胞)引起的摩擦激活了机械力传感器。这会产生一氧化氮(NO),使胎盘血管扩张,使更多的血液流向婴儿。本研究试图确定机械传感器Piezo1是否对胎胎盘内皮细胞(FpECs)中NO的产生很重要,以及该途径的步骤在小胎龄(SGA)婴儿中是否不同,其中胎盘血流经常改变。我们发现在健康的fpec中,血流增加了NO信号传导。我们认为,在SGA婴儿中,fpec有一氧化氮信号基线水平的增加,提示代偿驱动。用Piezo1化学激活剂Yoda1处理健康细胞和SGA细胞,上调NO信号。这表明Piezo1与NO有关,并且在SGA中,fpec具有进一步增加NO的能力。进一步的研究将确定Piezo1增强是否会导致胎盘血流增加。如果是这样,Piezo1可能成为开发治疗方法的新目标,以防止子宫内婴儿生长不良。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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