Aquaporin Abundance Research Articles

Elevated CO2 alleviates negative effects of salinity on broccoli (Brassica oleracea L. var Italica) plants by modulating water balance through aquaporins abundance

In the global change scenario, increased CO2 may favour water use efficiency (WUE) by plants. By contrast, in arid and semiarid areas, salinity may reduce water uptake from soils. However, an elevated WUE does not ensure a reduced water uptake and upon salinity this fact may constitute an advantage for plant tolerance. In this work, we aimed to determine the combined effects of enhanced [CO2] and salinity on the plant water status, in relation to the regulation of PIP aquaporins, in the root and leaf tissues of broccoli plants (Brassica oleracea L. var Italica), under these two environmental factors. Thus, different salinity concentrations (0, 60 and 90mM NaCl) were applied under ambient (380ppm) and elevated (800ppm) [CO2]. Under non-salinised conditions, stomatal conductance (Gs) and transpiration rate (E) decreased with rising [CO2] whereas water potential (Ψω) was maintained stable, which caused a reduction in the root hydraulic conductance (L0). In addition, PIP1 and PIP2 abundance in the roots was decreased compared to ambient [CO2]. Under salinity, the greater stomatal closure observed at elevated [CO2] – compared to that at ambient [CO2] – caused a greater reduction in Gs and E and allowed plants to maintain their water balance. In addition, a lower decrease in L0 under salt stress was observed at elevated [CO2], when comparing with the decrease at ambient [CO2]. Modifications in PIP1 and PIP2 abundance or their functionality in the roots is discussed. In fact, an improved water status of the broccoli plants treated with 90mM NaCl and elevated [CO2], evidenced by a higher Ψω, was observed together with higher photosynthetic rate and water use efficiency. These factors conferred on the salinised broccoli plants greater leaf area and biomass at elevated [CO2], in comparison with ambient [CO2]. We can conclude that, under elevated [CO2] and salt stress, the water flow is influenced by the tight control of the aquaporins in the roots and leaves of broccoli plants and that increased PIP1 and PIP2 abundance in these organs provides a mechanism of tolerance that maintains the plant water status.

Aquaporin 5 regulates cigarette smoke induced emphysema by modulating barrier and immune properties of the epithelium

Chronic obstructive pulmonary disease (COPD) causes significant morbidity and mortality. Cigarette smoke, the most common risk factor for COPD, induces airway and alveolar epithelial barrier permeability and initiates an innate immune response. Changes in abundance of aquaporin 5 (AQP5), a water channel, can affect epithelial permeability and immune response after cigarette smoke exposure. To determine how AQP5-derived epithelial barrier modulation affects epithelial immune response to cigarette smoke and development of emphysema, WT and AQP5−/− mice were exposed to cigarette smoke (CS). We measured alveolar cell counts and differentials, and assessed histology, mean-linear intercept (MLI), and surface-to-volume ratio (S/V) to determine severity of emphysema. We quantified epithelial-derived signaling proteins for neutrophil trafficking, and manipulated AQP5 levels in an alveolar epithelial cell line to determine specific effects on neutrophil transmigration after CS exposure. We assessed paracellular permeability and epithelial turnover in response to CS. In contrast to WT mice, AQP5−/− mice exposed to 6 months of CS did not demonstrate a significant increase in MLI or a significant decrease in S/V compared with air-exposed mice, conferring protection against emphysema. After sub-acute (4 weeks) and chronic (6 mo) CS exposure, AQP5−/− mice had fewer alveolar neutrophil but similar lung neutrophil numbers as WT mice. The presence of AQP5 in A549 cells, an alveolar epithelial cell line, was associated with increase neutrophil migration after CS exposure. Compared with CS-exposed WT mice, neutrophil ligand (CD11b) and epithelial receptor (ICAM-1) expression were reduced in CS-exposed AQP5−/− mice, as was secreted LPS-induced chemokine (LIX), an epithelial-derived neutrophil chemoattractant. CS-exposed AQP5−/− mice demonstrated decreased type I pneumocytes and increased type II pneumocytes compared with CS-exposed WT mice suggestive of enhanced epithelial repair. Absence of AQP5 protected against CS-induced emphysema with reduced epithelial permeability, neutrophil migration, and altered epithelial cell turnover which may enhance repair.

Age-related changes in expression in renal AQPs in response to congenital, partial, unilateral ureteral obstruction in rats

Previously we demonstrated that neonatally induced partial unilateral ureteral obstruction (PUUO) in rats is associated with changes in the abundance of renal acid-base transporters that were paralleled by reduction in renal functions dependent on the severity and duration of obstruction. The aim of the present study was to identify whether changes in renal aquaporin abundance are age-dependent. Semiquantitative immunoblotting and immunohistochemistry were used to examine the changes in abundance of AQP1, AQP2, p-S256AQP2 (AQP2 phosphorylated at consensus site Ser256) and AQP3 in the kidneys of rats with neonatally induced PUUO within the first 48 h of life, and then monitored for 7 or 14 weeks. Protein abundance of AQP2 and AQP3 increased in both obstructed and non-obstructed kidneys 7 weeks after induction of neonatal PUUO (PUUO-7W). In contrast, AQP1 and AQP2 protein abundance in the obstructed kidney were reduced after 14 weeks of PUUO (PUUO-14W). Importantly, pS256-AQP2 protein abundance was reduced in obstructed kidneys of both PUUO-7W and PUUO-14W. Immunohistochemistry confirmed the persistent pS256-AQP2 downregulation in both PUUO-7W and PUUO-14W rats. The study shows that the protein abundance of AQP1, AQP2, and AQP3 in the obstructed kidney is increased in PUUO-7W, which may be a compensatory phenomenon and reduced in PUUO-14W rats suggesting a time-/age-dependent dysregulation in response to PUUO. pS256-AQP2 protein abundance is reduced consistent with obstruction-induced direct effects in the apical part of the collecting duct principal cells in response to PUUO.

Could rapid diameter changes be facilitated by a variable hydraulic conductance?

Adequate radial water transport between elastic bark tissue and xylem is crucial in trees, because it smoothens abrupt changes in xylem water potential, greatly reducing the likelihood of suffering dangerous levels of embolism. The radial hydraulic conductance involved is generally thought to be constant. Evidence collected about variable root and leaf hydraulic conductance led us to speculate that radial hydraulic conductance in stem/branches might also be variable and possibly modulated by putative aquaporins. We therefore correlated diameter changes in walnut (Juglans regia L.) with changes in water potential, altered by perfusion of twig samples with D-mannitol solutions having different osmotic potentials. Temperature and cycloheximide (CHX; a protein synthesis inhibitor) treatments were performed. The temperature response and diameter change inhibition found in CHX-treated twigs underpinned our hypothesis that radial hydraulic conductance is variable and likely mediated by a putative aquaporin abundance and/or activity. Our data demonstrate that radial water transport in stem/branches can take two routes in parallel: an apoplastic and a cell-to-cell route. The contribution of either route depends on the hydraulic demand and is closely linked to a boost of putative aquaporins, causing radial conductance to be variable. This variability should be considered when interpreting and modelling diameter changes.

Root hydraulic conductance and aquaporin abundance respond rapidly to partial root-zone drying events in a riparian Melaleuca species

• Drying a portion of a root system (partial root-zone drying (PRD)) can induce partial stomatal closure, but this response is not always observed. We hypothesized that some of the variation in PRD response reflects adaptations to the native environment, where plants subjected to frequent PRD events may display a greater degree of root-level compensation. • Here, we examined PRD responses of Melaleuca argentea, a tree native to intermittent waterways in which PRD events are common. Seedlings were grown with part of their root system in soil and part in an aquatic compartment, mimicking conditions often observed in the field. • The aquatic roots initially provided two-thirds of total water uptake, but draining the aquatic compartment had no effect on stomatal conductance, so long as soil moisture remained c. 80% of field capacity. Water uptake from the soil compartment increased threefold within 24 h, with a corresponding transient threefold increase in root hydraulic conductance (L(p)), an increase in plasma membrane intrinsic protein 1 (PIP1) aquaporins at 24 h, and a decrease in PIP2 aquaporins by 48 h. • Our results demonstrate that PRD can induce rapid changes in L(p) and aquaporin expression in roots, which may play a role in short-term water uptake adjustments, particularly in species adapted to heterogeneous water availability.

Regulation of Aquaporins and Sodium Transporter Proteins in the Solitary Kidney in Response to Partial Ureteral Obstruction in Neonatal Rats

Unilateral ureteral obstruction (UUO) impairs function of the obstructed kidney, and the contralateral nonobstructed kidney compensates depending on the degree and duration of UUO. This study aimed to determine the hemodynamic and molecular changes in the solitary kidney in response to partial ureteral obstruction (PUO) where any compensation from the contralateral kidney was eliminated so that all observed changes in the kidney tissue occurred in the kidney with PUO. Newborn rats were subjected to unilateral left nephrectomy (UNX) within the first 48 h of life and a subset of UNX rats was subjected to severe PUO of the right kidney at day 14. Renal blood flow and whole kidney volume were measured with MRI at week 10. The renal protein abundance of aquaporin 1 (AQP1), AQP2 and AQP3 as well as Na,K-ATPase, NaPi-2 (type 2 sodium-phosphate cotransporter) and NHE3 (type 3 sodium-proton exchanger) were examined by immunoblotting and immunocytochemistry. At 10 weeks of age, the protein abundance of AQP2, AQP3, Na,K-ATPase, NaPi-2 and NHE3 were increased in response to PUO. In contrast, AQP1 expression was markedly decreased compared to sham-operated rats. These findings were confirmed by immunohistochemistry. GFR, urine osmolality and urine sodium excretion were reduced and kidney weight increased in response to PUO. In conclusion, the present study demonstrated major changes in the protein abundance of renal AQP1, AQP2 and AQP3 and sodium transporters in the solitary PUO kidney. These changes were paralleled by decreased urinary sodium excretion and a significant reduction in urinary osmolality from the obstructed kidney, suggesting a functional association between the molecular changes and the ability of the obstructed kidney to handle sodium and water in this solitary kidney model.

Renal responses to salinity change in snakes with and without salt glands

To understand renal responses to salinity change in aquatic reptiles, we examined the structure and function of the kidney in three species of snake: a marine species with a salt gland (Laticauda semifasciata), a marine species without a salt gland (Nerodia clarkii clarkii) and a freshwater species without a salt gland (Nerodia fasciata). Both marine species maintained relatively constant plasma ions, even after acclimation to saltwater. By contrast, both plasma Cl(-) and mortality increased with salinity in the freshwater species. To investigate putative renal ion regulatory mechanisms, we examined the distribution and abundance of Na(+)/K(+)-ATPase (NKA) and the Na(+)/K(+)/2Cl(-) cotransporter (NKCC2). In all species, NKA localized to the basolateral membranes of the distal tubule and the connecting segments and collecting ducts only; there was no effect of salinity on the distribution of NKA or on the abundance of NKA mRNA in any species. NKCC2 protein was undetectable in the kidney of any of the species and there was no effect of salinity on NKCC2 mRNA abundance. We also examined the distribution and abundance of aquaporin 3 (AQP3) in the kidney of these species; although putative AQP3 localized to the basolateral membranes of the connecting segments and collecting ducts of all three species, there was no effect of salinity on the localization of the protein or the abundance of the transcript. Interestingly, we found very few differences across species, suggesting that the snake kidney may play a trivial role in limiting habitat use.

Hyponatremia in patients treated with terlipressin: Mechanisms and implications for clinical practice

We have read with great interest the study by Solà et al.1 Two years ago, our group showed that terlipressin has an affinity to V2 receptors.2 Resultant hyponatremia has been suggested,2-4 and it is now supported by this large, retrospective clinical study with a relevant control group. The observed hyponatremia is likely a result of both V1a and V2 receptor activation. Terlipressin induces natriuresis via V1a receptor stimulation.5 The combination with V2 receptor–induced antidiuresis due to an increased abundance of aquaporin 2 in the renal collecting duct is likely responsible for the observed hyponatremia.2 The rise in natriuresis induced by terlipressin is most likely due to a combination of two actions: (1) a rise in blood pressure and a contribution of pressure natriuresis, in which an increase in arterial blood pressure reduces sodium reabsorption in the whole kidney, and (2) a stimulation of V1a receptors in the collecting duct, which induces natriuresis and counteracts the antinatriuretic effects of V2. In our study of 62 patients with bleeding esophageal varices, the serum sodium level decreased from 136 ± 6 to 130 ± 7, and the decrease in the serum sodium level correlated with the duration of treatment (Pearson correlation = −0.48, P < 0.001).4 A recent randomized study of bleeding esophageal varices also found the development of hyponatremia during terlipressin therapy to be related to the duration of the treatment.3 This reinforces the recommendation to use short-term terlipressin in patients with variceal bleeding to prevent side effects such as hyponatremia. Thus, the results of a recent study of patients with bleeding esophageal varices suggested that 2 days of terlipressin treatment combined with banding may be equally as effective as 5 days of terlipressin treatment.6 Aleksander Krag M.D., Ph.D.*, Søren Møller Dm.Sci. , Flemming Bendtsen Dm.Sci.*, * Departments of Gastroenterology, Hospital Hvidovre, Copenhagen University, Copenhagen, Denmark, Departments of Clinical Physiology, Hospital Hvidovre, Copenhagen University, Copenhagen, Denmark.

The response of broccoli plants to high temperature and possible role of root aquaporins

The effect of high root temperature on the water-uptake capability of broccoli plants ( Brassica oleracea cv. Parthenon), the status of the plasma membrane and the role of aquaporins in water transport through the plant plasma membrane were investigated. For this, different temperatures (25, 35, 40 and 45 °C) were assayed. A decrease of the PIP1 and PIP2 aquaporins abundance with increasing temperature was observed, but the P f values of protoplasts increased with the temperature. Changes of membrane fluidity were shown only at 40 °C, driving the membrane to a more rigid state. Also, the damaging effects of the stress, determined as electrolyte leakage (EL) in the whole root, and the possible osmotic adjustment, as an adaptive mechanism, were investigated. We propose that the increase in osmotic water permeability at higher temperature was not due to changes in the abundance of PIPs, but was probably due to an increase of permeability through the lipid bilayer. Also, the relation of the reduced gas exchange and aquaporins would provide a possible signal mechanism for acclimation to heat stress.

Membrane water permeability and aquaporin expression increase during growth of maize suspension cultured cells

Aquaporins (AQPs) are water channels that allow cells to rapidly alter their membrane water permeability. A convenient model for studying AQP expression and activity regulation is Black Mexican Sweet (BMS) maize cultured cells. In an attempt to correlate membrane osmotic water permeability coefficient (P(f)) with AQP gene expression, we first examined the expression pattern of 33 AQP genes using macro-array hybridization. We detected the expression of 18 different isoforms representing the four AQP subfamilies, i.e. eight plasma membrane (PIP), five tonoplast (TIP), three small basic (SIP) and two NOD26-like (NIP) AQPs. While the expression of most of these genes was constant throughout all growth phases, mRNA levels of ZmPIP1;3, ZmPIP2;1, ZmPIP2;2, ZmPIP2;4 and ZmPIP2;6 increased significantly during the logarithmic growth phase and the beginning of the stationary phase. The use of specific anti-ZmPIP antisera showed that the protein expression pattern correlated well with mRNA levels. Cell pressure probe and protoplast swelling measurements were then performed to determine the P(f). Interestingly, we found that the P(f) were significantly increased at the end of the logarithmic growth phase and during the steady-state phase compared to the lag phase, demonstrating a positive correlation between AQP abundance in the plasma membrane and the cell P(f).

199 EFFECT OF PRODUCTION SYSTEM AND BREED ON RELATIVE GENE EXPRESSION IN BOVINE EMBRYOS

Embryos produced in vivo and in vitro show morphological and developmental differences, which can be related to culture environment. Nevertheless, there are a few studies showing the effect of in vitro environment on embryos from different bovine subspecies, such as Gyr (Bos indicus) and Holstein (Bos taurus). The aim of this study was to evaluate the relative abundance of aquaporin 3 (AQP3) and ATPase-α1 (Na/K-ATPase alpha 1) transcripts in blastocysts produced in vivo or in vitro from Gyr and Holstein cattle. The production system effect (in vivo × in vitro) for Gyr cattle and the breed effect (Holstein × Gyr) for in vitro-produced embryos were evaluated. For each group, blastocysts (n = 15) distributed in 3 pools were used for RNA extraction (RNeasy MicroKit, Qiagen, Valencia, CA), followed by RNA amplification (Messageamp II amplification kit, Ambion-Applied Biosystems, Foster City, CA) and reverse transcription (SuperScript III First-Stand Synthesis Supermix, Invitrogen, Carlsbad, CA). The cDNA obtained were submitted to real-time PCR, using the H2a gene as endogenous control, and analyzed with REST software© using the pair wise fixed reallocation randomization Test. There was no difference (P &gt; 0.05) in gene expression for AQP3 and ATPase-α1 between in vivo- and in vitro-produced Gyr embryos, although the results suggest that the APQ3 gene was down-regulated (0.81 ± 0.31) and the ATPase-α1 gene was up-regulated (1.20 ± 0.65) in embryos produced in vitro. For breed effect within in vitro production system, ATPase-α1 gene was down-regulated in Holstein (0.56 ± 0.30) when compared with Gyr embryos (P &lt; 0.05). The same trend was observed for AQP3 (0.58 ± 0.25), but with no difference (P &gt; 0.05). In conclusion, the data suggest that embryo production system does not interfere with the transcript amount of the genes studied for Gyr cattle; however, the in vitro production system may have different effects on gene expression according to embryo breed. Other genes should be evaluated for a better understanding of these differences. Financial support: CNPq, Fapemig.

Effect of Low Root Temperature on Hydraulic Conductivity of Rice Plants and the Possible Role of Aquaporins

The role of root temperature T(R) in regulating the water-uptake capability of rice roots and the possible relationship with aquaporins were investigated. The root hydraulic conductivity Lp(r) decreased with decreasing T(R) in a measured temperature range between 10 degrees C and 35 degrees C. A single break point (T(RC) = 15 degrees C) was detected in the Arrhenius plot for steady-state Lp(r). The temperature dependency of Lp(r) represented by activation energy was low (28 kJ mol(-1)) above T(RC), but the value is slightly higher than that for the water viscosity. Addition of an aquaporin inhibitor, HgCl(2), into root medium reduced osmotic exudation by 97% at 25 degrees C, signifying that aquaporins play a major role in regulating water uptake. Below T(RC), Lp(r) declined precipitously with decreasing T(R) (E(a) = 204 kJ mol(-1)). When T(R) is higher than T(RC), the transient time for reaching the steady-state of Lp(r) after the immediate change in T(R) (from 25 degrees C) was estimated as 10 min, while it was prolonged up to 2-3 h when T(R) < T(RC). The Lp(r) was completely recovered to the initial levels when T(R) was returned back to 25 degrees C. Immunoblot analysis using specific antibodies for the major aquaporin members of PIPs and TIPs in rice roots revealed that there were no significant changes in the abundance of aquaporins during 5 h of low temperature treatment. Considering this result and the significant inhibition of water-uptake by the aquaporin inhibitor, we hypothesize that the decrease in Lp(r) when T(R) < T(RC) was regulated by the activity of aquaporins rather than their abundance.

Downregulation of UT-A1/UT-A3 Is Associated with Urinary Concentrating Defect in Glucocorticoid-Excess State

Excessive glucocorticoid hormone, as occurs with Cushing syndrome, is known to be associated with altered body water homeostasis, but the molecular mechanisms are unknown. In this study, rats treated with daily dexamethasone (Dex) for 14 d provided a model of Cushing syndrome. Compared with control rats, Dex-treated rats demonstrated increased mean arterial pressure, urine flow rate, and urinary excretion of both sodium and urea. Dex-treated rats had increased abundance of aquaporin 1 (AQP1), AQP3, and Na-K-2Cl co-transporter proteins and a marked reduction of the urea transporters UT-A1 and UT-A3. In response to an acute water load, Dex-treated rats increased water excretion more than control rats, but both groups exhibited similar AQP2 expression. In response to fluid deprivation, Dex-treated rats demonstrated an impaired urinary concentrating capacity: Urine flow rate was higher and urine osmolality was lower than control rats despite an increase in AQP1, AQP3, and Na-K-2Cl co-transporter expression. AQP2 expression was similar between the two groups, but UT-A1 and UT-A3 were decreased and urinary urea excretion was increased in Dex-treated rats. Because Dex-treated rats ingested less food and water compared with controls, paired food and water studies were performed; these substantiated the previous results. In summary, the alterations in body water observed with glucocorticoid excess may be a result, in part, of impaired urinary concentrating capacity; downregulation of UT-A1 and UT-A3 and increased urea excretion may contribute to this impairment.

Two different effects of calcium on aquaporins in salinity-stressed pepper plants

Two different effects of calcium were studied, respectively, in plasma membrane vesicles and in protoplasts isolated from roots of control pepper plants (Capsicum annuum L cv. California) or of plants treated with 50 mM NaCl, 10 mM CaCl(2) or 10 mM CaCl(2) + 50 mM NaCl. Under saline conditions, osmotic water permeability (P ( f )) values decreased in protoplasts and plasma membrane vesicles, and the same reduction was observed in the PIP1 aquaporin abundance, indicating inhibitory effects of NaCl on aquaporin functionality and protein abundance. The cytosolic Ca(2+) concentration, [Ca(2+)](cyt), was reduced by salinity, as observed by confocal microscope analysis. Two different actions of Ca(2+) were observed. On the one hand, increase in free cytosolic calcium concentrations associated with stress perception may lead to aquaporin closure. On the other hand, when critical requirements of Ca(2+) were reduced (by salinity), and extra-calcium would lead to an upregulation of aquaporins, indicating that a positive role of calcium at whole plant level combined with an inhibitory mechanism at aquaporin level may work in the regulation of pepper root water transport under salt stress. However, a link between these observations and other cell signalling in relation to water channel gating remains to be established.

Boric acid and salinity effects on maize roots. Response of aquaporins ZmPIP1 and ZmPIP2, and plasma membrane H+‐ATPase, in relation to water and nutrient uptake

Under saline conditions, an optimal cell water balance, possibly mediated by aquaporins, is important to maintain the whole-plant water status. Furthermore, excessive accumulation of boric acid in the soil solution can be observed in saline soils. In this work, the interaction between salinity and excess boron with respect to the root hydraulic conductance (L(0)), abundance of aquaporins (ZmPIP1 and ZmPIP2), ATPase activity and root sap nutrient content, in the highly boron- and salt-tolerant Zea mays L. cv. amylacea, was evaluated. A downregulation of root ZmPIP1 and ZmPIP2 aquaporin contents were observed in NaCl-treated plants in agreement with the L(0) measurements. However, in the H3BO3-treated plants differences in the ZmPIP1 and ZmPIP2 abundance were observed. The ATPase activity was related directly to the amount of ATPase protein and Na+ concentration in the roots, for which an increase in NaCl- and H3BO3+ NaCl-treated plants was observed with respect to untreated and H3BO3-treated plants. Although nutrient imbalance may result from the effect of salinity or H3BO3 alone, an ameliorative effect was observed when both treatments were applied together. In conclusion, our results suggest that under salt stress, the activity of specific membrane components can be influenced directly by boric acid, regulating the functions of certain aquaporin isoforms and ATPase as possible components of the salinity tolerance mechanism.

Transient receptor potential vanilloid 4 regulates aquaporin-5 abundance under hypotonic conditions

Aquaporin-5 (AQP5) is expressed in epithelia of lung, cornea, and various secretory glands, sites where extracellular osmolality is known to fluctuate. Hypertonic aquaporin (AQP) induction has been described, but little is known about the effects of a hypotonic environment on AQP abundance. We report that, when mouse lung epithelial cells were exposed to hypotonic medium, a dose-responsive decrease in AQP5 abundance was observed. Hypotonic reduction of AQP5 was blocked by ruthenium red, methanandamide, and miconazole, agents that inhibit the cation channel transient receptor potential vanilloid (TRPV) 4 present in lung epithelial cells. Several observations indicate that TRPV4 participates in hypotonic reduction of AQP5, including a requirement for extracellular calcium to achieve AQP5 reduction; an increase in intracellular calcium in mouse lung epithelial (MLE) cells after hypotonic stimulation; and reduction of AQP5 abundance after addition of the TRPV4 agonist 4alpha-Phorbol-12,13-didecanoate (4alpha-PDD). Similarly, addition of hypotonic PBS to mouse trachea in vivo decreased AQP5 within 1 h, an effect blocked by ruthenium red. To confirm a functional interaction, AQP5 was expressed in control or TRPV4-expressing human embryonic kidney (HEK) cells. Hypotonic reduction of AQP5 was observed only in the presence of TRPV4 and was blocked by ruthenium red. Combined with earlier studies, these observations indicate that AQP5 abundance is tightly regulated along a range of osmolalities and that AQP5 reduction by extracellular hypotonicity can be mediated by TRPV4. These findings have direct relevance to regulation of membrane water permeability and water homeostasis in epithelia of the lung and other organs.

The Role of Aquaporins and Membrane Damage in Chilling and Hydrogen Peroxide Induced Changes in the Hydraulic Conductance of Maize Roots

When chilling-sensitive plants are chilled, root hydraulic conductance (L(o)) declines precipitously; L(o) also declines in chilling-tolerant plants, but it subsequently recovers, whereas in chilling-sensitive plants it does not. As a result, the chilling-sensitive plants dry out and may die. Using a chilling-sensitive and a chilling-tolerant maize genotype we investigated the effect of chilling on L(o), and its relationship to osmotic water permeability of isolated root cortex protoplasts, aquaporin gene expression, aquaporin abundance, and aquaporin phosphorylation, hydrogen peroxide (H(2)O(2)) accumulation in the roots and electrolyte leakage from the roots. Because chilling can cause H(2)O(2) accumulation we also determined the effects of a short H(2)O(2) treatment of the roots and examined the same parameters. We conclude from these studies that the recovery of L(o) during chilling in the chilling-tolerant genotype is made possible by avoiding or repairing membrane damage and by a greater abundance and/or activity of aquaporins. The same changes in aquaporins take place in the chilling-sensitive genotype, but we postulate that membrane damage prevents the L(o) recovery. It appears that the aquaporin response is necessary but not sufficient to respond to chilling injury. The plant must also be able to avoid the oxidative damage that accompanies chilling.

Aquaporin water channels AQP1 and AQP3, are expressed in equine articular chondrocytes

Chondrocytes exist in an unusual and highly variable ionic and osmotic environment in the extracellular matrix of articular cartilage. Alterations to the ionic and osmotic environment of chondrocytes influence the volume and ionic content of the cells, which, in turn, modifies the rate at which extracellular matrix macromolecules are synthesized and degraded. Thus, regulation of the water and solute content of chondrocytes will profoundly affect their anabolic and catabolic functions. The water content of cells is effectively influenced by the abundance of aquaporin (AQP) water channels. Recent studies have shown that several AQP water channel isoforms are expressed in chondrocytes from Meckel’s cartilage, developing teeth and other orofacial tissues. The aim of the present investigation was to determine if chondrocytes from equine articular cartilage express AQP water channels. Polyclonal antibodies to AQP1, AQP2 and AQP3 were used in conjunction with immunohistochemistry, immunoblotting and quantitative flow cytometry to determine if AQP1, AQP2 and AQP3 are expressed in equine articular chondrocytes. Our studies show that AQP1 and AQP3 are expressed by chondrocytes in articular cartilage in situ and in isolated chondrocytes. We found no evidence for expression of AQP2, the vasopressin-regulated water channel in chondrocytes. AQP1 and AQP3 may be involved in the transport of water and small solutes and osmotically active metabolites across the chondrocyte plasma membrane during volume regulatory behaviour. AQP1 may be involved in transporting metabolic water. AQP3 may participate in the transport of glycerol and structurally related molecules.

Altered expression of renal aquaporins and Na+transporters in rats treated with L-type calcium blocker

Nifedipine, a calcium antagonist, has diuretic and natriuretic properties. However, the molecular mechanisms by which these effects are produced are poorly understood. We examined kidney abundance of aquaporins (AQP1, AQP2, and AQP3) and major sodium transporters [type 3 Na/H exchanger (NHE-3); type 2 Na-Pi cotransporter (NaPi-2); Na-K-ATPase; type 1 bumetanide-sensitive cotransporter (BSC-1); and thiazide-sensitive Na-Cl cotransporter (TSC)] as well as inner medullary abundance of AQP2, phosphorylated-AQP2 (p-AQP2), AQP3, and calcium-sensing receptor (CaR). Rats treated with nifedipine orally (700 mg/kg) for 19 days had a significant increase in urine output, whereas urinary osmolality and solute-free water reabsorption were markedly reduced. Consistent with this, immunoblotting revealed a significant decrease in the abundance of whole kidney AQP2 (47 +/- 7% of control rats, P < 0.05) and in inner medullary AQP2 (60 +/- 7%) as well as in p-AQP2 abundance (17 +/- 6%) in nifedipine-treated rats. In contrast, whole kidney AQP3 abundance was significantly increased (219 +/- 28%). Of potential importance in modulating AQP2 levels, the abundance of CaR in the inner medulla was significantly increased (295 +/- 25%) in nifedipine-treated rats. Nifedipine treatment was also associated with increased urinary sodium excretion. Consistent with this, semiquantitative immunoblotting revealed significant reductions in the abundance of proximal tubule Na(+) transporters: NHE-3 (3 +/- 1%), NaPi-2 (53 +/- 12%), and Na-K-ATPase (74 +/- 5%). In contrast, the abundance of the distal tubule Na-Cl cotransporter (TSC) was markedly increased (240 +/- 29%), whereas BSC-1 in the thick ascending limb was not altered. In conclusion, 1) increased urine output and reduced urinary concentration in nifedipine-treated-rats may, in part, be due to downregulation of AQP2 and p-AQP2 levels; 2) CaR might be involved in the regulation of water reabsorption in the inner medulla collecting duct; 3) reduced expression of proximal tubule Na(+) transporters (NHE-3, NaPi-2, and Na, K-ATPase) may be involved in the increased urinary sodium excretion; and 4) increase in TSC expression may occur as a compensatory mechanism.

Profiling of renal tubule Na+ transporter abundances in NHE3 and NCC null mice using targeted proteomics.

The Na+-H+ exchanger NHE3 and the thiazide-sensitive Na+-Cl- cotransporter NCC are the major apical sodium transporters in the proximal convoluted tubule and the distal convoluted tubule of the kidney, respectively. We investigated the mechanism of compensation that allows maintenance of sodium balance in NHE3 knockout mice and in NCC knockout mice. We used a so-called 'targeted proteomics' approach, which profiles the entire renal tubule with regard to changes in Na+ transporter and aquaporin abundance in response to the gene deletions. Specific antibodies to the Na+ transporters and aquaporins expressed along the nephron were utilized to determine the relative abundance of each transporter. Semiquantitative immunoblotting was used which gives an estimate of the percentage change in abundance of each transporter in knockout compared with wild-type mice. In NHE3 knockout mice three changes were identified which could compensate for the loss of NHE3-mediated sodium absorption. (a) The proximal sodium-phosphate cotransporter NaPi-2 was markedly upregulated. (b) In the collecting duct, the 70 kDa form of the y-subunit of the epithelial sodium channel, ENaC, exhibited an increase in abundance. This is thought to be an aldosterone-stimulated form of y-ENaC. (c) Glomerular filtration was significantly reduced. In the NCC knockout mice, amongst all the sodium transporters expressed along the renal tubule, only the 70 kDa form of the y-subunit of the epithelial sodium channel, ENaC, exhibited an increase in abundance. In conclusion, both mouse knockout models demonstrated successful compensation for loss of the deleted transporter. More extensive adaptation occurred in the case of the NHE3 knockout, presumably because NHE3 is responsible for much more sodium absorption in normal mice than in NCC knockout mice.