Introducing a special series: Membrane proteins, epithelial transport, and kidney physiology

IF 5.6 2区 医学 Q1 PHYSIOLOGY Acta Physiologica Pub Date : 2023-03-09 DOI:10.1111/apha.13958
Henrik Dimke
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引用次数: 1

Abstract

Membrane proteins, facilitating transport across epithelia, are fundamental for a range of essential physiological processes throughout the organism. For instance, the regulation of epithelial transport is critically important for the homeostatic control of electrolyte and fluid balance, as well as many other solutes. Adjusting these epithelial transport mechanisms is at the core of a myriad of diverse physiological mechanisms, including the maintenance of blood pressure, glucose homeostasis, nutrient uptake, and the removal of waste products into urine. Knowledge of these epithelial transport mechanisms informs of their perturbations in pathophysiological conditions, as exemplified in cystic fibrosis, where the transmembrane conductance regulator anion channel disrupts epithelial chloride transport in airways and other organs,1 or in familial hyperkalemia and hypertension where pathogenic variants in the with-no-lysine (WNK) protein kinases alter renal epithelial transport.2 Understanding these epithelial transport processes open the door to targeted treatments.

Seminal discoveries of membrane proteins being essential components include the sodium-potassium ATPase by Jens Christian Skou3 and aquaporin water channels by Peter Agre.4 In recognition, both pioneers became Nobel laureates. Knowledge of the epithelial transport processes oftentimes precedes the identification of the responsible protein, while at other times the identification of a protein allows the identification of the transport process. These discoveries have shaped our understanding of epithelial transport physiology. None more so, than our understanding of the kidney and its central role in maintaining homeostasis.

The journal Acta Physiologica, previously titled Acta Physiologica Scandinavica (1940–2005) and Skandinavisches Archiv für Physiologie (1889–1939) provide longstanding contributions to this field. For instance, in 1929, Norn found that the diurnal rhythm of urinary sodium, chloride, potassium, and water excretion could be reversed when studying a nurse on night shift.5 In 1937, Krogh developed methods to study ion uptake and reported on the ability of the frog to absorb salt through the skin against large concentration gradients.6 In 1951, Ussing and Zerahn published the development of an apparatus to simultaneously determine electric current and sodium transport through isolated frog skin,7 now known as the Ussing chamber system. And in 1961 when Lassen et al, investigated the correlation between renal oxygen uptake and sodium reabsorption in the mammalian kidney.8 These are just a few highlights and by no means an exhaustive overview of manuscripts published in Acta Physiologica on these topics. Furthermore, many manuscripts have been published within these fields over the latest years, including multiple recent works.9-11

To honor this tradition, we invite you to take part in a special series on the topic of membrane proteins and epithelial transport in physiology and pathophysiology. We look forward to receiving original articles for consideration for publication in this series. Naturally, reviews are also welcome. Given the importance of epithelial transport in the kidney, a particular focus is placed hereon. However, as editor of this special series, I welcome studies on epithelial transport from any organ system.

The author has no financial interests to declare.

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介绍一个特殊的系列:膜蛋白、上皮转运和肾脏生理学
膜蛋白,促进跨上皮运输,是整个生物体一系列基本生理过程的基础。例如,上皮运输的调节对于电解质和液体平衡以及许多其他溶质的稳态控制至关重要。调节这些上皮运输机制是许多不同生理机制的核心,包括维持血压、葡萄糖稳态、营养摄取和废物进入尿液的清除。这些上皮转运机制的知识告诉我们它们在病理生理条件下的扰动,例如在囊性纤维化中,跨膜电导调节阴离子通道破坏气道和其他器官中的上皮氯离子转运1,或在家族性高钾血症和高血压中,无赖氨酸(WNK)蛋白激酶的致病变异改变肾上皮转运2了解这些上皮运输过程为靶向治疗打开了大门。延斯·克里斯蒂安·斯库发现的钠-钾三磷酸腺苷酶和彼得·格里发现的水通道蛋白都是膜蛋白必不可少的组成部分。因此,两位先驱都获得了诺贝尔奖。对上皮运输过程的了解通常先于相关蛋白的鉴定,而在其他时候,蛋白质的鉴定允许对运输过程的鉴定。这些发现塑造了我们对上皮运输生理学的理解。最重要的是,我们对肾脏及其在维持体内平衡中的核心作用的理解。《生理学报》(原名《斯堪的纳维亚生理学报》,1940-2005)和《斯堪的纳维亚生理学报》(1889-1939)为这一领域做出了长期贡献。例如,在1929年,诺恩在研究夜班护士时发现尿钠、氯、钾和水排泄的昼夜节律可以逆转1937年,克拉夫发明了研究离子吸收的方法,并报道了青蛙在大浓度梯度下通过皮肤吸收盐的能力1951年,乌辛和泽拉恩发表了一项仪器的发展成果,该仪器可以同时测定电流和钠通过分离的青蛙皮肤的传输,现在被称为乌辛室系统。1961年Lassen等研究了哺乳动物肾脏摄氧量与钠重吸收之间的关系这些只是几个亮点,绝不是在《生理学学报》上发表的关于这些主题的手稿的详尽概述。此外,近年来在这些领域发表了许多手稿,包括许多最近的作品。为了纪念这一传统,我们邀请您参加生理学和病理生理学中膜蛋白和上皮运输的特别系列讲座。我们期待收到原创文章,以考虑在本系列中发表。当然,评论也是受欢迎的。鉴于上皮运输在肾脏中的重要性,在此特别强调。然而,作为这个特别系列的编辑,我欢迎来自任何器官系统的上皮运输研究。作者没有经济利益需要申报。
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来源期刊
Acta Physiologica
Acta Physiologica 医学-生理学
CiteScore
11.80
自引率
15.90%
发文量
182
审稿时长
4-8 weeks
期刊介绍: Acta Physiologica is an important forum for the publication of high quality original research in physiology and related areas by authors from all over the world. Acta Physiologica is a leading journal in human/translational physiology while promoting all aspects of the science of physiology. The journal publishes full length original articles on important new observations as well as reviews and commentaries.
期刊最新文献
Correction to "Beneficial effects of MGL-3196 and BAM15 combination in a mouse model of fatty liver disease". Issue Information Impaired suppression of fatty acid release by insulin is a strong predictor of reduced whole-body insulin-mediated glucose uptake and skeletal muscle insulin receptor activation. Differential production of mitochondrial reactive oxygen species between mouse (Mus musculus) and crucian carp (Carassius carassius) A quantitative analysis of bestrophin 1 cellular localization in mouse cerebral cortex.
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