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罕见的肾脏钠钾转运体基因突变会导致转运功能受损。

Rare mutations in renal sodium and potassium transporter genes exhibit impaired transport function.

机构信息

Department of Physiology, University of Maryland Medical School, Baltimore, Maryland, USA.

出版信息

Curr Opin Nephrol Hypertens. 2014 Jan;23(1):1-8. doi: 10.1097/01.mnh.0000437204.84826.99.

DOI:10.1097/01.mnh.0000437204.84826.99
PMID:24253496
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4007692/
Abstract

PURPOSE OF REVIEW

Recent efforts to explore the genetic underpinnings of hypertension revealed rare mutations in kidney salt transport genes contribute to blood pressure (BP) variation and hypertension susceptibility in the general population. The current review focuses on these latest findings, highlighting a discussion about the rare mutations and how they affect the transport function.

RECENT FINDINGS

Rare mutations that confer a low BP trait and resistance to hypertension have recently been extensively studied. Physiological and biochemical analyses of the affected renal salt transport molecules [NKCC2 (SLC12A1), ROMK (KCNJ1), and NCC (SLC12A3)] revealed that most of the mutations do, in fact, cause a loss of transport function. The mutations disrupt the transport by many different mechanisms, including altering biosynthetic processing, trafficking, ion transport, and regulation.

SUMMARY

New insights into the genetic basis of hypertension have recently emerged, supporting a major role of rare, rather than common, gene variants. Many different rare mutations have been found to affect the functions of different salt transporter genes by different mechanisms, yet all confer the same BP phenotype. These studies reinforce the critical roles of the kidney, and renal salt transport in BP regulation and hypertension.

摘要

目的综述

最近探索高血压遗传基础的努力揭示了肾脏盐转运基因的罕见突变导致了一般人群血压(BP)的变化和高血压易感性。本综述重点介绍了这些最新发现,强调了对罕见突变及其对转运功能影响的讨论。

最近的发现

最近广泛研究了赋予低 BP 特征和高血压抗性的罕见突变。受影响的肾脏盐转运分子[NKCC2(SLC12A1)、ROMK(KCNJ1)和 NCC(SLC12A3)]的生理和生化分析表明,大多数突变实际上确实导致转运功能丧失。这些突变通过多种不同的机制破坏转运,包括改变生物合成加工、运输、离子转运和调节。

总结

最近高血压遗传基础的新见解表明,罕见而非常见的基因变异起主要作用。许多不同的罕见突变已被发现通过不同的机制影响不同盐转运基因的功能,但都导致相同的 BP 表型。这些研究强化了肾脏和肾脏盐转运在 BP 调节和高血压中的关键作用。

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