H95 Is a pH-Dependent Gate in Aquaporin 4

Kaptan, Shreyas; Assentoft, Mette; Schneider, H. P. G.; Fenton, Robert A.; Deitmer, Joachim W.; MacAulay, Nanna; Groot, Bert L. de

doi:10.1016/j.str.2015.08.020

Cited by 52 publications

(60 citation statements)

References 85 publications

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“…3, in BvPIP2;2 the pore radius at the Ar/R region is of approximately 0. 72 A, a similar value was previously reported for SoPIP2;1 [10] and other aquaporins [6,23,36] (Fig. 3A).…”

Section: Resultssupporting

confidence: 89%

“…The triggering events that promote the open-closed transition in PIP channels can be a drop in cytoplasmic pH, an increase in Ca 2+ concentrations or the dephosphorylation of specific serine residues [17][18][19][20][21][22]. Permeability regulation by pH has been reported for different aquaporins such as mammalian AQP3, AQP4, AQP5, AQP7 and plant AtTIP2;1, VvTIP2;1 among others [23][24][25][26][27][28]. But in particular, cytosolic acidification is a well-studied trigger for PIP channels gating as pH regulation of water transport has been described in red beet, Arabidopsis thaliana, strawberry, grape, and tobacco PIP aquaporins [17,20,[29][30][31][32][33].…”

Section: Introductionmentioning

confidence: 99%

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Gating in plant plasma membrane aquaporins: the involvement of leucine in the formation of a pore constriction in the closed state

et al. 2019

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The control of water permeability in plant PIP2 aquaporins has become a paradigmatic case study of the capping mechanism for pore closure in water channels. From structural data, it has been postulated that the gating process in PIP2 involves a conformational rearrangement in cytosolic loopD that generates an obstruction to the transport of water molecules inside the aquaporin pore. BvPIP2;2 is a PIP2 aquaporin from Beta vulgaris whose pH response has been thoroughly characterized. In this work, we study the participation of Leu206 in BvPIP2;2 gating triggered by cytosolic acidification and show that this residue acts as a plug that blocks water transport. Based on data obtained from in silico and in vitro studies, we demonstrate that Leu206, one of the residues lining the pore, is responsible for ~ 60% of water blockage. Cell osmotic swelling experiments and atomistic molecular dynamics simulations indicate that the replacement of Leu206 by an Ala residue maintains high water permeability under conditions where the pore is expected to be closed. The present work demonstrates that Leu206, located at the cytoplasmic entry of the channel, constitutes a crucial pH‐sensitive steric gate regulating water transport in PIP aquaporins.

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“…3, in BvPIP2;2 the pore radius at the Ar/R region is of approximately 0. 72 A, a similar value was previously reported for SoPIP2;1 [10] and other aquaporins [6,23,36] (Fig. 3A).…”

Section: Resultssupporting

confidence: 89%

Section: Introductionmentioning

confidence: 99%

Gating in plant plasma membrane aquaporins: the involvement of leucine in the formation of a pore constriction in the closed state

et al. 2019

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“…An even more rapid change in water transport activity can be achieved by gating 7,8 whereby the water conducting pore of a gated aquaporin can be opened or closed through mechanical means, analogous to the opening and closing of a bottle with a hinged cap 9 . Aquaporin gating may be triggered by diverse types of external stimuli, including phosphorylation 10,11 and pH 10,12,13 . Voltage 14 and membrane-mediated mechanical stress 11 have also been suggested as external factors inducing aquaporin gating.…”

Section: Introductionmentioning

confidence: 99%

Temperature dependence of protein-water interactions in a gated yeast aquaporin

Aponte-Santamaría

Fischer

Båth

et al. 2017

Sci Rep

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Regulation of aquaporins is a key process of living organisms to counteract sudden osmotic changes. Aqy1, which is a water transporting aquaporin of the yeast Pichia pastoris, is suggested to be gated by chemo-mechanical stimuli as a protective regulatory-response against rapid freezing. Here, we tested the influence of temperature by determining the X-ray structure of Aqy1 at room temperature (RT) at 1.3 Å resolution, and by exploring the structural dynamics of Aqy1 during freezing through molecular dynamics simulations. At ambient temperature and in a lipid bilayer, Aqy1 adopts a closed conformation that is globally better described by the RT than by the low-temperature (LT) crystal structure. Locally, for the blocking-residue Tyr31 and the water molecules inside the pore, both LT and RT data sets are consistent with the positions observed in the simulations at room-temperature. Moreover, as the temperature was lowered, Tyr31 adopted a conformation that more effectively blocked the channel, and its motion was accompanied by a temperature-driven rearrangement of the water molecules inside the channel. We therefore speculate that temperature drives Aqy1 from a loosely- to a tightly-blocked state. This analysis provides high-resolution structural evidence of the influence of temperature on membrane-transport channels.

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“…The relative stability of the two resulting states, open and closed, may depend on small changes in the microenvironment, such as variations of pH. Indeed, a pH-dependent gating mechanism was recently obtained from in silico and in vitro studies [35], ascribing to His95 located in AQP4 cytoplasmic end the role of regulating channel permeability. Phosphorylation of AQP4 has also been demonstrated with opposed effects depending on the residue that is phosphorylated.…”

Section: Resultsmentioning

confidence: 99%

Rat Aquaporin-5 Is pH-Gated Induced by Phosphorylation and Is Implicated in Oxidative Stress

Rodrigues

Mósca

Martins

et al. 2016

IJMS

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Aquaporin-5 (AQP5) is a membrane water channel widely distributed in human tissues that was found up-regulated in different tumors and considered implicated in carcinogenesis in different organs and systems. Despite its wide distribution pattern and physiological importance, AQP5 short-term regulation was not reported and mechanisms underlying its involvement in cancer are not well defined. In this work, we expressed rat AQP5 in yeast and investigated mechanisms of gating, as well as AQP5’s ability to facilitate H2O2 plasma membrane diffusion. We found that AQP5 can be gated by extracellular pH in a phosphorylation-dependent manner, with higher activity at physiological pH 7.4. Moreover, similar to other mammalian AQPs, AQP5 is able to increase extracellular H2O2 influx and to affect oxidative cell response with dual effects: whereas in acute oxidative stress conditions AQP5 induces an initial higher sensitivity, in chronic stress AQP5 expressing cells show improved cell survival and resistance. Our findings support the involvement of AQP5 in oxidative stress and suggest AQP5 modulation by phosphorylation as a novel tool for therapeutics.

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H95 Is a pH-Dependent Gate in Aquaporin 4

Cited by 52 publications

References 85 publications

Gating in plant plasma membrane aquaporins: the involvement of leucine in the formation of a pore constriction in the closed state

Gating in plant plasma membrane aquaporins: the involvement of leucine in the formation of a pore constriction in the closed state

Temperature dependence of protein-water interactions in a gated yeast aquaporin

Rat Aquaporin-5 Is pH-Gated Induced by Phosphorylation and Is Implicated in Oxidative Stress

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