Department of Hepatology and Gastroenterology, Aarhus University Hospital, Aarhus, Denmark.
UCL Institute of Liver and Digestive Health, University College London, London, United Kingdom.
Am J Physiol Gastrointest Liver Physiol. 2021 Apr 1;320(4):G474-G483. doi: 10.1152/ajpgi.00136.2020. Epub 2021 Jan 6.
Our study provides novel findings of experimental hypokalemia reducing urea cycle functionality and thereby severely increasing plasma ammonia. This is pathophysiologically interesting because plasma ammonia increases during hypokalemia by a hitherto unknown mechanism, which may be particular important in relation to the unexplained link between hypokalemia and hepatic encephalopathy. Potassium deficiency decreases gene expression, protein synthesis, and growth. The urea cycle maintains body nitrogen homeostasis including removal of toxic ammonia. Hyperammonemia is an obligatory trait of liver failure, increasing the risk for hepatic encephalopathy, and hypokalemia is reported to increase ammonia. We aimed to clarify the effects of experimental hypokalemia on the in vivo capacity of the urea cycle, on the genes of the enzymes involved, and on ammonia concentrations. Female Wistar rats were fed a potassium-free diet for 13 days. Half of the rats were then potassium repleted. Both groups were compared with pair- and free-fed controls. The following were measured: in vivo capacity of urea-nitrogen synthesis (CUNS); gene expression (mRNA) of urea cycle enzymes; plasma potassium, sodium, and ammonia; intracellular potassium, sodium, and magnesium in liver, kidney, and muscle tissues; and liver sodium/potassium pumps. Liver histology was assessed. The diet induced hypokalemia of 1.9 ± 0.4 mmol/L. Compared with pair-fed controls, the in vivo CUNS was reduced by 34% ( < 0.01), gene expression of argininosuccinate synthetase 1 () was decreased by 33% ( < 0.05), and plasma ammonia concentrations were eightfold elevated ( < 0.001). Kidney and muscle tissue potassium contents were markedly decreased but unchanged in liver tissue. Protein expressions of liver sodium/potassium pumps were unchanged. Repletion of potassium reverted all the changes. Hypokalemia decreased the capacity for urea synthesis via gene effects. The intervention led to marked hyperammonemia, quantitatively explainable by the compromised urea cycle. Our findings motivate clinical studies of patients with liver disease.
我们的研究提供了实验性低钾血症降低尿素循环功能的新发现,从而严重增加血浆氨。这在病理生理学上很有趣,因为低钾血症时血浆氨增加的机制目前尚不清楚,这可能与低钾血症和肝性脑病之间未被解释的联系特别相关。钾缺乏会降低基因表达、蛋白质合成和生长。尿素循环维持着体内氮平衡,包括去除有毒的氨。高氨血症是肝功能衰竭的必然特征,增加了肝性脑病的风险,并且低钾血症据报道会增加氨。我们旨在阐明实验性低钾血症对尿素循环的体内能力、相关酶的基因表达以及氨浓度的影响。雌性 Wistar 大鼠连续 13 天喂食低钾饮食。然后一半大鼠补充钾。将两组与配对和自由喂养对照组进行比较。测量以下指标:尿素氮合成的体内能力(CUNS);尿素循环酶的基因表达(mRNA);血浆钾、钠和氨;肝、肾和肌肉组织中的细胞内钾、钠和镁;以及肝钠/钾泵。评估了肝组织学。饮食引起的低钾血症为 1.9±0.4mmol/L。与配对喂养对照组相比,体内 CUNS 降低了 34%(<0.01),精氨酸琥珀酸合成酶 1()的基因表达降低了 33%(<0.05),血浆氨浓度升高了 8 倍(<0.001)。肾脏和肌肉组织的钾含量明显减少,但肝脏组织的钾含量不变。肝钠/钾泵的蛋白表达不变。补充钾可逆转所有变化。低钾血症通过基因效应降低了尿素合成的能力。该干预导致明显的高氨血症,可通过受损的尿素循环定量解释。我们的发现促使对肝病患者进行临床研究。
