Institute of Veterinary Physiology, University of Leipzig , Germany.
J Appl Physiol (1985). 2017 Dec 1;123(6):1487-1500. doi: 10.1152/japplphysiol.00436.2017. Epub 2017 Aug 31.
The gastrointestinal epithelium possesses adaptation mechanisms to cope with huge variations in blood flow and subsequently oxygenation. Since sufficient energy supply is crucial under hypoxic conditions, glucose uptake especially must be regulated by these adaptation mechanisms. Therefore, we investigated glucose transport under hypoxic conditions. Jejunal epithelia of rabbits were incubated in Ussing chambers under short-circuit current conditions. Hypoxia was simulated by gassing with 1% O instead of 100% O. The activity of sodium-coupled glucose transporter-1 (SGLT-1) was assessed by measuring the increase of short circuit current ( I) after the addition of 2 mM glucose to the mucosal buffer solution. We observed decreased activity of SGLT-1 after hypoxia compared with control conditions. To investigate underlying mechanisms, epithelia were exposed to agonists and antagonists of AMP-activated protein kinase (AMPK) before assessment of SGLT-1-mediated transport and the pAMPK/AMPK protein ratio. Preincubation with the antagonist restored SGLT-1 activity under hypoxic conditions to the level of control conditions, indicating an involvement of AMPK in the downregulation of SGLT-1 activity under hypoxia, which was confirmed in Western blot analysis of pAMPK/AMPK. Transepithelial flux studies using radioactively labeled glucose, ortho-methyl-glucose, fructose, and mannitol revealed no changes after hypoxic incubation. Therefore, we could exclude a decreased transepithelial glucose transport rate and increased paracellular conductance under hypoxia. In conclusion, our study hints at a decreased activity of SGLT-1 under hypoxic conditions in an AMPK-dependent manner. However, transepithelial transport of glucose is maintained. Therefore, we suggest other transport mechanisms, especially glucose transporter 1 and/or 2 to substitute SGLT-1 under hypoxia. NEW & NOTEWORTHY To our knowledge, this is the first approach to simulate hypoxia and study its effects in the jejunal epithelium using the Ussing chamber technique. We were able show that AMPK plays a role in the downregulation of SGLT-1 and that there seems to be an upregulation of other glucose transport mechanisms in the apical membrane of lagomorph jejunum epithelium under hypoxia, securing the epithelial energy supply and thus integrity.
胃肠道上皮具有适应机制,以应对血流和随之而来的氧合的巨大变化。由于在缺氧条件下充足的能量供应至关重要,因此葡萄糖摄取必须特别受到这些适应机制的调节。因此,我们研究了缺氧条件下的葡萄糖转运。将兔子的回肠上皮在短路电流条件下孵育于 Ussing 室中。通过用 1%O 而不是 100%O 进行充气来模拟缺氧。通过向粘膜缓冲液中添加 2mM 葡萄糖来测量短电路电流(I)的增加来评估钠偶联葡萄糖转运蛋白-1(SGLT-1)的活性。与对照条件相比,我们观察到缺氧后 SGLT-1 的活性降低。为了研究潜在的机制,在用激动剂和拮抗剂处理 AMP 激活的蛋白激酶(AMPK)之前,将上皮暴露于 SGLT-1 介导的转运和 pAMPK/AMPK 蛋白比。缺氧条件下 SGLT-1 活性的预孵育恢复到对照条件的水平,表明 AMPK 参与了缺氧下 SGLT-1 活性的下调,这在 Western blot 分析中得到了 pAMPK/AMPK 的证实。使用放射性标记的葡萄糖、邻甲氧基葡萄糖、果糖和甘露醇进行的跨上皮通量研究表明,缺氧孵育后没有变化。因此,我们可以排除缺氧下跨上皮葡萄糖转运率降低和细胞旁通透性增加。总之,我们的研究表明,在 AMPK 依赖性方式下,SGLT-1 的活性在缺氧条件下降低。然而,葡萄糖的跨上皮转运得到维持。因此,我们建议其他转运机制,特别是葡萄糖转运蛋白 1 和/或 2 在缺氧下替代 SGLT-1。
新的和值得注意的是,据我们所知,这是首次使用 Ussing 室技术模拟缺氧并研究其对回肠上皮的影响。我们能够表明 AMPK 在 SGLT-1 的下调中发挥作用,并且似乎在兔回肠上皮的顶膜中有其他葡萄糖转运机制的上调,以确保上皮细胞的能量供应,从而维持其完整性。
