ClC Channels and Transporters: Structure, Physiological Functions, and Implications in Human Chloride Channelopathies

Poroca, Diogo R.; Pelis, Ryan M.; Chappe, Valérie

doi:10.3389/fphar.2017.00151

Cited by 95 publications

(59 citation statements)

References 206 publications

(403 reference statements)

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“…The primary protein responsible for chloride transport into the intestinal lumen is the apically located cystic fibrosis transmembrane receptor (CFTR) [71]. However, another contributor to transepithelial chloride transport within intestinal epithelium is the voltage-gated ClC-2 protein, one of nine mammalian proteins belonging to the chloride channel (ClC) protein family [72]. ClC-2 has been shown to localize in the plasma membrane at tight junction complexes within mouse intestinal epithelium [73] or has plasmalemmal basolateral localization within guinea pig colons [74], suggesting species-or tissue-specific localization of ClC-2.…”

Section: Clc-2 and Intestinal Repairmentioning

confidence: 99%

The Integral Role of Tight Junction Proteins in the Repair of Injured Intestinal Epithelium

Slifer

Blikslager

2020

IJMS

158

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The intestinal epithelial monolayer forms a transcellular and paracellular barrier that separates luminal contents from the interstitium. The paracellular barrier consists of a highly organized complex of intercellular junctions that is primarily regulated by apical tight junction proteins and tight junction-associated proteins. This homeostatic barrier can be lost through a multitude of injurious events that cause the disruption of the tight junction complex. Acute repair after injury leading to the reestablishment of the tight junction barrier is crucial for the return of both barrier function as well as other cellular functions, including water regulation and nutrient absorption. This review provides an overview of the tight junction complex components and how they link to other plasmalemmal proteins, such as ion channels and transporters, to induce tight junction closure during repair of acute injury. Understanding the components of interepithelial tight junctions and the mechanisms of tight junction regulation after injury is crucial for developing future therapeutic targets for patients experiencing dysregulated intestinal permeability.

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Section: Clc-2 and Intestinal Repairmentioning

confidence: 99%

The Integral Role of Tight Junction Proteins in the Repair of Injured Intestinal Epithelium

Slifer

Blikslager

2020

IJMS

158

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“…Clearly, a deep understanding of the mechanisms involved in protein and gene regulation by Cl − is important to understand better the pathologies associated with different Cl − channels (channelopathies) (Statland, Phillips & Trivedi, 2014;Suetterlin, Mannikko & Hanna, 2014;Poroca, Pelis Menegazzi et al (2000) & Chappe, 2017). The role of Cl − channels in disease has been extensively reviewed elsewhere (Kunzelmann & Mall, 2002;Pedemonte & Galietta, 2014;Hoffmann et al, 2015;Abeyrathne, Chami & Stahlberg, 2016;Ito, 2016;Whitlock & Hartzell, 2016;Poroca et al, 2017;Kamaleddin, 2018). The early history of the role of Cl − in muscle was recently reviewed by Hutter (2017).…”

Section: CL − Effects In Eukaryotic Cellsmentioning

confidence: 99%

The chloride anion as a signalling effector

Valdivieso

Santa‐Coloma

2019

Biological Reviews

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The specific role of the chloride anion (Cl−) as a signalling effector or second messenger has been increasingly recognized in recent years. It could represent a key factor in the regulation of cellular homeostasis. Changes in intracellular Cl− concentration affect diverse cellular functions such as gene and protein expression and activities, post‐translational modifications of proteins, cellular volume, cell cycle, cell proliferation and differentiation, membrane potential, reactive oxygen species levels, and intracellular/extracellular pH. Cl− also modulates functions in different organelles, including endosomes, phagosomes, lysosomes, endoplasmic reticulum, and mitochondria. A better knowledge of Cl− signalling could help in understanding the molecular and metabolic changes seen in pathologies with altered Cl− transport or under physiological conditions. Here we review relevant evidence supporting the role of Cl− as a signalling effector.

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“…So far, several types of chloride channels have been identified, either by its molecular or its functional properties, including voltage‐dependent chloride channels (ClC),cystic fibrosis transmembrane regulator (CFTR), calcium‐activated chloride channels (CaCC), and volume‐regulated chloride channels (VRAC) (Poroca et al. ; Jentsch ; Grinstein et al. ).…”

Section: Introductionmentioning

confidence: 99%

“…Chloride channels have been found to be expressed in all types of cells, both in prokaryotes and in eukaryotes, participating in a wide variety of physiological processes, including excitability, cell proliferation, motility, cell volume regulation, and cellular recognition of their environment, among many others (Nilius and Droogmans 2003). So far, several types of chloride channels have been identified, either by its molecular or its functional properties, including voltage-dependent chloride channels (ClC),cystic fibrosis transmembrane regulator (CFTR), calcium-activated chloride channels (CaCC), and volume-regulated chloride channels (VRAC) (Poroca et al 2017;Jentsch 1996;Grinstein et al 1982). Although they have been described in almost all types of cells and tissues, there are only a few reports describing chloride channels in protozoans (Delgadillo et al 2002;Salas-Casas et al 2006;Moreno-Galindo et al 2014).…”

Section: Introductionmentioning

confidence: 99%

Injection of mRNA isolated from trophozoites of Giardia intestinalis induces expression of three types of chloride currents in Xenopus laevis oocytes.

Ponce¹,

Toro²,

Jimenez³

et al. 2019

Physiol Rep

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Giardia lamblia is one of the most important worldwide causes of intestinal infections, yet little is known about its cellular physiology, especially the diversity of ionic channels that this parasite expresses. In this work, we show that injection of mRNA isolated from trophozoites of Giardia , into Xenopus laevis oocytes, induces expression of three types of chloride currents (here referred to as IC l‐G1, IC l‐G2, and IC l‐G3), which have different biophysical and pharmacological properties. IC l‐G1 currents show inward rectification and voltage dependence are enhanced by hypotonicity, show a selectivity sequence of (I > Br > Cl > F), and are inhibited by NPPB , DIDS , SITS , 9 AC , DPC , and Zinc. These findings suggest that IC l‐G1 is the result of expression of chloride channels related to ClC2. IC l‐G2 currents show outward rectification and are dependent of intracellular calcium, its selectivity sequence is (Cl > Br > I > F) and are inhibited by NPPB , DIDS , SITS , 9 AC , DPC , niflumic acid, tannic acid, and benzbromarone. These findings suggest that they are produced by calcium dependent chloride channels (Ca CC ). The third type of currents ( IC l‐G3) appears only after a hypoosmotic challenge, and has similar properties to those described for IC l‐swell, such as outward rectification, instant activation, and slow inactivation at large depolarizing voltages. They were blocked by NPPB , DIDS , 9 AC , NI f, DCPIB , and tamoxifen. Our results indicate that Giardia intestinalis has at least three types of anion conductances.

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ClC Channels and Transporters: Structure, Physiological Functions, and Implications in Human Chloride Channelopathies

Cited by 95 publications

References 206 publications

The Integral Role of Tight Junction Proteins in the Repair of Injured Intestinal Epithelium

The Integral Role of Tight Junction Proteins in the Repair of Injured Intestinal Epithelium

The chloride anion as a signalling effector

Injection of mRNA isolated from trophozoites of Giardia intestinalis induces expression of three types of chloride currents in Xenopus laevis oocytes.

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