Paradoxes in magnesium transport in type 1 Bartter's syndrome and Gitelman's syndrome: a modeling analysis.

Pritha Dutta, Anita T Layton
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Abstract

Type 1 Bartter's syndrome and Gitelman's syndrome are characterized by mutations in two key renal Na+ transporters, Na-K-2Cl cotransporter (NKCC2) and Na-Cl cotransporter (NCC). Since these two transporters play an important role in regulating magnesium (Mg2+) and calcium (Ca2+) transport in the kidney, significant alterations in the transport of these two electrolytes are observed in type 1 Bartter's syndrome and Gitelman's syndrome. In this study, we used our sex-specific computational models of renal electrolyte transport in rats to understand the complex compensatory mechanisms, in terms of alterations in tubular dimensions and ion transporter activities, that lead to Mg2+ and Ca2+ preservation or wasting in these two genetic disorders. Given the sexual dimorphism in renal transporter patterns, we also assessed how the magnitude of these alterations may differ between males and females. Model simulations showed that in type 1 Bartter's syndrome, nephron adaptations prevent salt wasting and favor Mg2+ preservation but not Ca2+, whereas in Gitelman's syndrome, those adaptations favor Ca2+ preservation over Mg2+. In addition, our models predicted that the compensatory alterations in tubular dimensions and ion transporter activities are stronger in females than in males.NEW & NOTEWORTHY Although changes in Ca2+ excretion in type 1 Bartter's syndrome and Gitelman's syndrome are well understood, Mg2+ excretion displays an interesting paradox. This computational modeling study provides insights into how renal adaptations in these two disorders impact Ca2+ and Mg2+ transport along different nephron segments. Model simulations showed that nephron adaptations favor Mg2+ preservation over Ca2+ in Bartter's syndrome and Ca2+ preservation over Mg2+ in Gitelman's syndrome and are stronger in females than in males.

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1 型巴特综合征和吉特曼综合征的镁转运悖论:模型分析。
1 型巴特综合征和吉特曼综合征的特征是两个关键的肾脏 Na+ 转运体(Na-K-2Cl 共转运体 (NKCC2) 和 Na-Cl 共转运体 (NCC))发生突变。由于这两个转运体在调节肾脏中镁(Mg2+)和钙(Ca2+)的转运方面发挥着重要作用,因此在 1 型巴特氏综合征和吉特曼氏综合征中观察到这两种电解质的转运发生了显著变化。在本研究中,我们利用大鼠肾电解质转运的性别特异性计算模型来了解这两种遗传疾病中导致 Mg2+ 和 Ca2+ 保存或消耗的复杂代偿机制,即肾小管尺寸和离子转运体活性的改变。考虑到肾脏转运体模式的性别双态性,我们还评估了这些改变的程度在男性和女性之间可能存在的差异。模型模拟显示,在 1 型巴特氏综合征中,肾小球适应性可防止盐耗竭,并有利于保存 Mg2+,但不利于保存 Ca2+;而在 Gitelman 综合征中,这些适应性有利于保存 Ca2+,不利于保存 Mg2+。此外,我们的模型预测,女性肾小管尺寸和离子转运活性的代偿性改变比男性更强。
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