Nanna MacAulay

Water transport between CNS compartments: contributions of aquaporins and cotransporters.

Large water fluxes continuously take place between the different compartments of the brain as well as between the brain parenchyma and the blood or cerebrospinal fluid. This water flux is tightly regulated but may be disturbed under pathological conditions that lead to brain edema formation or hydrocephalus. The molecular pathways by which water molecules cross the cell membranes of the brain are not well-understood, although the discovery of aquaporin 4 (AQP4) in the brain improved our understanding of some of these transport processes, particularly under pathological conditions. In the present review we introduce another family of transport proteins as water transporters, namely the cotransporters and the glucose uniport GLUT1. In direct contrast to the aquaporins, these proteins have an inherent ability to transport water against an osmotic gradient. Some of them may also function as water pores in analogy to the aquaporins. The putative role of cotransport proteins and uniports for the water flux into the glial cells, through the choroid plexus and across the endothelial cells of the blood-brain-barrier will be discussed and compared to the contribution of the aquaporins.

Contributions of the Na+/K+-ATPase, NKCC1, and Kir4.1 to hippocampal K+ clearance and volume responses

Network activity in the brain is associated with a transient increase in extracellular K+ concentration. The excess K+ is removed from the extracellular space by mechanisms proposed to involve Kir4.1‐mediated spatial buffering, the Na+/K+/2Cl− cotransporter 1 (NKCC1), and/or Na+/K+‐ATPase activity. Their individual contribution to [K+]o management has been of extended controversy. This study aimed, by several complementary approaches, to delineate the transport characteristics of Kir4.1, NKCC1, and Na+/K+‐ATPase and to resolve their involvement in clearance of extracellular K+ transients. Primary cultures of rat astrocytes displayed robust NKCC1 activity with [K+]o increases above basal levels. Increased [K+]o produced NKCC1‐mediated swelling of cultured astrocytes and NKCC1 could thereby potentially act as a mechanism of K+ clearance while concomitantly mediate the associated shrinkage of the extracellular space. In rat hippocampal slices, inhibition of NKCC1 failed to affect the rate of K+ removal from the extracellular space while Kir4.1 enacted its spatial buffering only during a local [K+]o increase. In contrast, inhibition of the different isoforms of Na+/K+‐ATPase reduced post‐stimulus clearance of K+ transients. The astrocyte‐characteristic α2β2 subunit composition of Na+/K+‐ATPase, when expressed in Xenopus oocytes, displayed a K+ affinity and voltage‐sensitivity that would render this subunit composition specifically geared for controlling [K+]o during neuronal activity. In rat hippocampal slices, simultaneous measurements of the extracellular space volume revealed that neither Kir4.1, NKCC1, nor Na+/K+‐ATPase accounted for the stimulus‐induced shrinkage of the extracellular space. Thus, NKCC1 plays no role in activity‐induced extracellular K+ recovery in native hippocampal tissue while Kir4.1 and Na+/K+‐ATPase serve temporally distinct roles. GLIA 2014;62:608–622

Water transport in the brain: Role of cotransporters

It is generally accepted that cotransporters transport water in addition to their normal substrates, although the precise mechanism is debated; both active and passive modes of transport have been suggested. The magnitude of the water flux mediated by cotransporters may well be significant: both the number of cotransporters per cell and the unit water permeability are high. For example, the Na(+)-glutamate cotransporter (EAAT1) has a unit water permeability one tenth of that of aquaporin (AQP) 1. Cotransporters are widely distributed in the brain and participate in several vital functions: inorganic ions are transported by K(+)-Cl(-) and Na(+)-K(+)-Cl(-) cotransporters, neurotransmitters are reabsorbed from the synaptic cleft by Na(+)-dependent cotransporters located on glial cells and neurons, and metabolites such as lactate are removed from the extracellular space by means of H(+)-lactate cotransporters. We have previously determined water transport capacities for these cotransporters in model systems (Xenopus oocytes, cell cultures, and in vitro preparations), and will discuss their role in water homeostasis of the astroglial cell under both normo- and pathophysiologal situations. Astroglia is a polarized cell with EAAT localized at the end facing the neuropil while the end abutting the circulation is rich in AQP4. The water transport properties of EAAT suggest a new model for volume homeostasis of the extracellular space during neural activity.

KCNQ1 channels sense small changes in cell volume.

Many important physiological processes involve changes in cell volume, e.g. the transport of salt and water in epithelial cells and the contraction of cardiomyocytes. In this study, we show that voltage‐gated KCNQ1 channels, which are strongly expressed in epithelial cells or cardiomyocytes, and KCNQ4 channels, expressed in hair cells and the auditory tract, are tightly regulated by small cell volume changes when co‐expressed with aquaporin 1 water‐channels (AQP1) in Xenopus oocytes. The KCNQ1 and KCNQ4 current amplitudes precisely reflect the volume of the oocytes. By contrast, the related KCNQ2 and KCNQ3 channels, which are prominently expressed in neurons, are insensitive to cell volume changes. The sensitivity of the KCNQ1 and KCNQ4 channels to cell volume changes is independent of the presence of the auxiliary KCNE1–3 subunits, although modulated by KCNE1 in the case of KCNQ1. Incubation of the oocytes in cytochalasin D and experiments with truncated KCNQ1 channels suggest that KCNQ1 channels sense cell volume changes through interactions between the cytoskeleton and the N‐terminus of the channel protein. From our results we propose that KCNQ1 and KCNQ4 channels play an important role in cell volume control, e.g. during transepithelial transport of salt and water.

Glial K+ Clearance and Cell Swelling: Key Roles for Cotransporters and Pumps

An important feature of neuronal signalling is the increased concentration of K+ in the extracellular space. The K+ concentration is restored to its original basal level primarily by uptake into nearby glial cells. The molecular mechanisms by which K+ is transferred from the extracellular space into the glial cell are debated. Although spatial buffer currents may occur, their quantitative contribution to K+ clearance is uncertain. The concept of spatial buffering of K+ precludes intracellular K+ accumulation and is therefore (i) difficult to reconcile with the K+ accumulation repeatedly observed in glial cells during K+ clearance and (ii) incompatible with K+-dependent glial cell swelling. K+ uptake into non-voltage clamped cultured glial cells is carried out by the Na+/K+-ATPase and the Na+/K+/Cl− cotransporter in combination. In brain slices and intact optic nerve, however, only the Na+/K+-ATPase has been demonstrated to be involved in stimulus-evoked K+ clearance. The glial cell swelling associated with K+ clearance is prevented under conditions that block the activity of the Na+/K+/Cl− cotransporter. The Na+/K+/Cl− cotransporter is activated by increased K+ concentration and cotransports water along with its substrates. It thereby serves as a K+-dependent molecular water pump under conditions of increased extracellular K+ load.

Water transport by the human Na+-coupled glutamate cotransporter expressed in Xenopus oocytes

1 The water transport properties of the human Na+‐coupled glutamate cotransporter (EAAT1) were investigated. The protein was expressed in Xenopus laevis oocytes and electrogenic glutamate transport was recorded by two‐electrode voltage clamp, while the concurrent water transport was monitored as oocyte volume changes. 2 Water transport by EAAT1 was bimodal. Water was cotransported along with glutamate and Na+ by a mechanism within the protein. The transporter also sustained passive water transport in response to osmotic challenges. The two modes could be separated and could proceed in parallel. 3 The cotransport modality was characterized in solutions of low Cl− concentration. Addition of glutamate promptly initiated an influx of 436 ± 55 water molecules per unit charge, irrespective of the clamp potential. 4 The cotransport of water occurred in the presence of adverse osmotic gradients. In accordance with the Gibbs equation, energy was transferred within the protein primarily from the downhill fluxes of Na+ to the uphill fluxes of water. 5 Experiments using the cation‐selective ionophore gramicidin showed no unstirred layer effects. Na+ currents in the ionophore did not lead to any significant initial water movements. 6 In the absence of glutamate, EAAT1 contributed a passive water permeability (Lp) of (11.3 ± 2.0) X 10−6 cm s−1 (osmol l−1)−1. In the presence of glutamate, Lp was about 50 % higher for both high and low Cl− concentrations. 7 The physiological role of EAAT1 as a molecular water pump is discussed in relation to cellular volume homeostasis in the nervous system.

TRPV4 and AQP4 Channels Synergistically Regulate Cell Volume and Calcium Homeostasis in Retinal Müller Glia

Brain edema formation occurs after dysfunctional control of extracellular volume partly through impaired astrocytic ion and water transport. Here, we show that such processes might involve synergistic cooperation between the glial water channel aquaporin 4 (AQP4) and the transient receptor potential isoform 4 (TRPV4), a polymodal swelling-sensitive cation channel. In mouse retinas, TRPV4 colocalized with AQP4 in the end feet and radial processes of Müller astroglia. Genetic ablation of TRPV4 did not affect the distribution of AQP4 and vice versa. However, retinas from Trpv4−/− and Aqp4−/− mice exhibited suppressed transcription of genes encoding Trpv4, Aqp4, and the Kir4.1 subunit of inwardly rectifying potassium channels. Swelling and [Ca2+]i elevations evoked in Müller cells by hypotonic stimulation were antagonized by the selective TRPV4 antagonist HC-067047 (2-methyl-1-[3-(4-morpholinyl)propyl]-5-phenyl-N-[3-(trifluoromethyl)phenyl]-1H-pyrrole-3-carboxamide) or Trpv4 ablation. Elimination of Aqp4 suppressed swelling-induced [Ca2+]i elevations but only modestly attenuated the amplitude of Ca2+ signals evoked by the TRPV4 agonist GSK1016790A [(N-((1S)-1-{[4-((2S)-2-{[(2,4-dichlorophenyl)sulfonyl]amino}-3-hydroxypropanoyl)-1-piperazinyl]carbonyl}-3-methylbutyl)-1-benzothiophene-2-carboxamide]. Glial cells lacking TRPV4 but not AQP4 showed deficits in hypotonic swelling and regulatory volume decrease. Functional synergy between TRPV4 and AQP4 during cell swelling was confirmed in the heterologously expressing Xenopus oocyte model. Importantly, when the swelling rate was osmotically matched for AQP4-positive and AQP4-negative oocytes, TRPV4 activation became independent of AQP4. We conclude that AQP4-mediated water fluxes promote the activation of the swelling sensor, whereas Ca2+ entry through TRPV4 channels reciprocally modulates volume regulation, swelling, and Aqp4 gene expression. Therefore, TRPV4–AQP4 interactions constitute a molecular system that fine-tunes astroglial volume regulation by integrating osmosensing, calcium signaling, and water transport and, when overactivated, triggers pathological swelling. SIGNIFICANCE STATEMENT We characterize the physiological features of interactions between the astroglial swelling sensor transient receptor potential isoform 4 (TRPV4) and the aquaporin 4 (AQP4) water channel in retinal Müller cells. Our data reveal an elegant and complex set of mechanisms involving reciprocal interactions at the level of glial gene expression, calcium homeostasis, swelling, and volume regulation. Specifically, water influx through AQP4 drives calcium influx via TRPV4 in the glial end foot, which regulates expression of Aqp4 and Kir4.1 genes and facilitates the time course and amplitude of hypotonicity-induced swelling and regulatory volume decrease. We confirm the crucial facets of the signaling mechanism in heterologously expressing oocytes. These results identify the molecular mechanism that contributes to dynamic regulation of glial volume but also provide new insights into the pathophysiology of glial reactivity and edema formation.

Role of multiple phosphorylation sites in the COOH-terminal tail of aquaporin-2 for water transport: evidence against channel gating

Arginine vasopressin (AVP)-regulated phosphorylation of the water channel aquaporin-2 (AQP2) at serine 256 (S256) is essential for its accumulation in the apical plasma membrane of collecting duct principal cells. In this study, we examined the role of additional AVP-regulated phosphorylation sites in the COOH-terminal tail of AQP2 on protein function. When expressed in Xenopus laevis oocytes, prevention of AQP2 phosphorylation at S256A (S256A-AQP2) reduced osmotic water permeability threefold compared with wild-type (WT) AQP2-injected oocytes. In contrast, prevention of AQP2 single phosphorylation at S261 (S261A), S264 (S264A), and S269 (S269A), or all three sites in combination had no significant effect on water permeability. Similarly, oocytes expressing S264D-AQP2 and S269D-AQP2, mimicking AQP2 phosphorylated at these residues, had similar water permeabilities to WT-AQP2-expressing oocytes. The use of high-resolution confocal laser-scanning microscopy, as well as biochemical analysis demonstrated that all AQP2 mutants, with the exception of S256A-AQP2, had equal abundance in the oocyte plasma membrane. Correlation of osmotic water permeability relative to plasma membrane abundance demonstrated that lack of phosphorylation at S256, S261, S264, or S269 had no effect on AQP2 unit water transport. Similarly, no effect on AQP2 unit water transport was observed for the 264D and 269D forms, indicating that phosphorylation of the COOH-terminal tail of AQP2 is not involved in gating of the channel. The use of phosphospecific antibodies demonstrated that AQP2 S256 phosphorylation is not dependent on any of the other phosphorylation sites, whereas S264 and S269 phosphorylation depend on prior phosphorylation of S256. In contrast, AQP2 S261 phosphorylation is independent of the phosphorylation status of S256.

Cotransport of water by Na+–K+–2Cl− cotransporters expressed in Xenopus oocytes: NKCC1 versus NKCC2

•  It is a fundamental, yet unsolved physiological question how water transport is coupled to ion transport. •  Na+–K+–2Cl‐ cotransporters (NKCCs) play a fundamental role in cellular water and ion homeostasis. In epithelial cells the NKCC1 isoform is located unilaterally and plays a key role in secretory processes such as salivary production. •  The other isoform, NKCC2, is located primarily to kidney distal tubule where it is responsible for salt reabsorption. •  The present investigation shows that the NKCC1 isoform cotransports water together with the ions by a mechanism closely associated with the protein itself. In contrast the NKCC2 isoform transports ions but not water. •  Our data establish that coupling between salt and water transport takes place in certain cotransporters, for example NKCC1. Such proteins may constitute the link between the metabolic energy used by the Na+,K+‐ATPase, the cationic gradients established, and water transport.

Vasopressin-dependent short-term regulation of aquaporin 4 expressed in Xenopus oocytes.

Aquaporin 4 (AQP4) is abundantly expressed in the perivascular glial endfeet in the central nervous system (CNS), where it is involved in the exchange of fluids between blood and brain. At this location, AQP4 contributes to the formation and/or the absorption of the brain edema that may arise following pathologies such as brain injuries, brain tumours, and cerebral ischemia. As vasopressin and its G-protein-coupled receptor (V1(a)R) have been shown to affect the outcome of brain edema, we have investigated the regulatory interaction between AQP4 and V1(a)R by heterologous expression in Xenopus laevis oocytes. The water permeability of AQP4/V1(a)R-expressing oocytes was reduced in a vasopressin-dependent manner, as a result of V1(a)R-dependent internalization of AQP4. Vasopressin-dependent internalization was not observed in AQP9/V1(a)R-expressing oocytes. The regulatory interaction between AQP4 and V1(a)R involves protein kinase C (PKC) activation and is reduced upon mutation of Ser(180) on AQP4 to an alanine. Thus, the present study demonstrates at the molecular level a functional link between the vasopressin receptor V1(a)R and AQP4. This functional interaction between AQP4 and V1(a)R may prove to be a potential therapeutic target in the prevention and treatment of brain edema.