Role of aquaporins in lung liquid physiology

Aquaporins (AQPs) are small, integral membrane proteins that facilitate water transport across cell membranes in response to osmotic gradients. Water transport across epithelia and endothelia in the peripheral lung and airways occurs during airway hydration, alveolar fluid transport and submucosal gland secretion. Several AQPs are expressed in the lung and airways: AQP1 in microvascular endothelia, AQP3 and AQP4 in airway epithelia, and AQP5 in type I alveolar epithelial cells, submucosal gland acini, and a subset of airway epithelial cells. Phenotype analysis of transgenic knockout mice lacking AQPs has defined their roles in the lung and airways. AQP1 and AQP5 provide the principal route for osmotically driven water transport between airspace and capillary compartments; however, alveolar fluid clearance in the neonatal and adult lung is not affected by their deletion, nor is lung fluid accumulation in experimental models of lung injury. In the airways, though AQP3 and AQP4 facilitate osmotic water transport, their deletion does not impair airway hydration, regulation of airway surface liquid, or fluid absorption. In contrast to these negative findings, AQP5 deletion in submucosal glands reduced fluid secretion by >50%. The substantially slower fluid transport in the lung compared to renal and secretory epithelia probably accounts for the lack of functional significance of AQPs in the lung and airways. Recent data outside of the lung implicating the involvement of AQPs in cell migration and proliferation suggests possible new roles for lung AQPs to be explored.     

Immunolocalization of water channel aquaporins in the nasal olfactory mucosa

Aquaporins (AQPs), membrane water channel proteins expressed in various tissues and organs, serve in the transfer of water and small solutes across the membrane. We raised antibodies to AQPs using isoform-specific synthetic peptides and surveyed their expression in the rat nasal olfactory and respiratory mucosae. AQP1, AQP3, AQP4, and AQP5 were detected by immunohistochemical and immunoblotting analyses. AQP1 was expressed in the endothelial cells of blood vessels and the surrounding connective tissue cells in the olfactory and respiratory mucosae. AQP1 may be involved in water transfer across the blood vessel wall. In the olfactory epithelium, no AQP was detected in the olfactory sensory cells. Instead, AQP3 was abundant in the olfactory epithelium, where it was localized in the supporting cells and basal cells. Expression of AQP3 was mostly restricted to the basal cells in the respiratory epithelium. In marked contrast, AQP4 was abundant in the respiratory epithelium, but its abundance was limited to the basal cells in the olfactory epithelium. In the Bowman's gland, AQP5 was localized in the apical membrane in the secretory acinar cells, whereas AQP3 and AQP4 were found in the basolateral membrane. Similar localization was seen in its duct cells. These results showed a distinct localization pattern for AQPs in the olfactory epithelium. AQP3 and AQP4 in the supporting cells and basal cells may play an important role in generating and maintaining the specific microenvironment around the olfactory sensory cells. AQP3, AQP4, and AQP5 in the Bowman's gland may serve in the secretion to generate the microenvironment at the apical surface of the olfactory dendrites for odorant reception.     

Bronchiolar expression of aquaporin-3 (AQP3) in rat lung and its dynamics in pulmonary oedema

Aquaporins (AQPs) are water channel proteins that permit osmotically driven water movement. To determine their dynamics in pulmonary oedema, we examined the expression of mRNA and protein for AQP1, AQP3, AQP4, and AQP5 in the lungs of normal and thiourea-treated rats. In the thiourea group, lung water content increased significantly (vs. controls) with the peak at around 4 h. Semi-quantitative RT-PCR showed that AQP3 mRNA in the thiourea group rose significantly, peaking at around 4–8 h. The expression of AQP1, AQP4, AQP5, ENaC and CFTR mRNA each decreased significantly some time after the peak in lung water content. Immunoblot analysis showed that glycosylated AQP3 protein was increased 4–10 h after treatment. Expression of the other AQP proteins was not significantly altered, except for that of AQP4. Immunohistochemical examination revealed that AQP1 was expressed in endothelia, AQP3 in the basal cells of the large airways and in cuboidal cells in the bronchioles, AQP4 in the basolateral membrane of airway cells and AQP5 in type-I pneumocytes. Our results suggest that AQP3 is expressed not only in large airways, but also in bronchioles, and is related to water movement in pulmonary oedema.     

Immunohistochemical Localization of the Aquaporins AQP1, AQP3, AQP4, and AQP5 in the Mouse Respiratory System

Aquaporins are membrane water channel proteins that function mainly in water transfer across cellular membranes. In our present study, we investigated the immunohistochemical distribution of aquaporin 1 (AQP1), AQP3, AQP4, and AQP5 in the mouse respiratory system by immunofluorescence, immunoperoxidase, and immunoelectron microscopy. AQP3, AQP4, and AQP5 are expressed in epithelial cells, whereas AQP1 is expressed in subepithelial connective tissues and capillaries. In the airway surface epithelia from the nasal cavity to the intrapulmonary bronchioles, AQP5 was found to be mainly localized to the luminal side and both AQP3 and AQP4 to the abluminal side. In the alveolar epithelium, AQP5 is localized to the apical membranes of both type I and type II alveolar cells. Compared with the previous studies on the rat respiratory system, in which AQP5 is restricted to the alveolar type I cells and absent from the airway surface epithelia, we found that AQP5 in the mouse is much more widely distributed throughout the surface epithelia. These results suggest that AQP5 has a critical role in water-handling, such as the maintenance of airway surface liquid and clearance of alveolar fluid in the mouse respiratory system.     

Upregulation of AQP3 and AQP5 induced by dexamethasone and ambroxol in A549 cells

Aquaporins (AQPs) are membrane channel proteins that play roles in the regulation of water permeability in many tissues. AQP1 and AQP5 expressed in lung provide the principal route for osmotically driven water transport. In the airways, AQP3 and AQP4 facilitate water transport. Dexamethasone and ambroxol are often used to treat patients with pulmonary diseases accompanied by airway hypersecretion. The role of AQPs in these effective treatments has not been addressed. In this study, we analyzed the expression of AQPs in a human airway epithelial cell line (A549 cells) and showed that AQP3 and 5, but not AQP1 and 4, were expressed in A549 cells. Both dexamethasone and ambroxol stimulated the expression of AQP3 and 5 at the mRNA and protein levels. The data suggest potential roles of AQP3 and 5 in the regulation of airway hypersecretion, perhaps ultimately providing a target for treating such diseases.     

Evidence that aquaporin-8 is located in the basolateral membrane of rat submandibular gland acinar cells

It is possible that, during primary saliva formation, aquaporins (AQPs) facilitate transcellular water flow across acinar cells to the lumina of salivary glands. In the rat submandibular gland (rSMG) AQP5 is localized in the apical membranes of acinar cells. The presence of a basolateral AQP in the same cell type has not been reported. We have therefore used immunofluorescence confocal microscopy to determine the subcellular localization of a newly discovered aquaporin, AQP8, in rSMG epithelial cells. The antibodies we used were made against the amino- or carboxyl-terminus (anti-rAQP8NT and anti-rAQP8CT, respectively) of an AQP8 cloned from rat pancreas and liver (rAQP8). Two lines of evidence suggest that both antibodies are suitable for immunolocalization studies. First, results of immunofluorescence confocal microscopy studies show that both antibodies bind to the plasma membranes of 293 cells infected with an adenovirus encoding rAQP8. Second, results of immunoblots of membranes from infected cells suggest that both antibodies bind to glycosylated and non-glycosylated forms of rAQP8. When tested in frozen sections of rSMG, we could not detect the binding of anti-rAQP8NT to any membranes. In contrast, anti-rAQP8CT binds to the basolateral membranes of acinar (but not ductal) epithelia, suggesting that rAQP8 resides in the basolateral membranes of acinar cells. Lack of anti-rAQPNT binding to basolateral membranes suggests that this epitope is not available in the membranes. Our evidence for the basolateral localization of rAQP8 in acinar cells, coupled with previous findings that AQP5 is localized apically in the same cells, raises the possibility that water crosses the acinar epithelium through these channels during primary saliva formation.     

胎儿发育中水通道蛋白的免疫组化观察

目的观察胎儿器官和组织发育过程中水通道蛋白(AQPs)的表达特征,初步探讨AQPs对胎儿发育进程的生物意义。方法14～38周胎儿共12例,取用肾脏、肺脏、唾液腺、甲状腺和胃等器官,常规固定、石蜡包埋和切片;用免疫组化S-P法,检测AQPs(AQP1、AQP2和AQP4)在胎儿不同胎龄器官组织中的表达。结果胎儿肾脏中AQPs定位于近端小管和集合管系统;胎肺中AQPs的表达随肺泡发育分化而迁移,始终定位于肺泡上皮;晚期胎肺中AQPs于肺泡及呼吸道上皮均有表达;胎16周起检出AQPs反应于唾液腺、胃腺和胰腺等消化腺,同时甲状腺中AQPs在滤泡上皮也有活跃表达。结论胎肾中AQPs的表达与肾的重吸收功能直接相关;胎肺内AQPs的表达反映肺泡上皮分化的轨迹,其调节水分的作用为肺泡发育提供空间;AQPs介导细胞内外水分的转运不但调节消化腺的分泌还参与调节甲状腺滤泡的激素合成和分泌过程。表明AQPs在胎儿发育过程,对各器官中水转运功能的成熟起重要作用。     

Downregulation of aquaporin 5 induced by vector-based short hairpin RNA and its effect on MUC5AC gene expression in human airway submucosal gland cells

The aquaporins (AQPs) are a family of homologous water channels expressed in many epithelial and endothelial cells, however no reliable and non-toxic inhibitors of AQPs have been reported yet. Our researchers have analyzed the changes of AQP5 expression induced by vector-based short hairpin RNA (shRNA) in the human airway submucosal gland cell line (SPC-A1) and observed its regulation on the expression of MUC5AC gene. Localizations of AQP5 and MUC5AC in SPC-A1cells were detected by Immunofluorescence. AQP5 mRNA was significantly reduced by 75.1% one day after transfection with specific shRNA, named shAQP5. However, the significant suppression of AQP5 protein did not appear until day 5 after transfection. MUC5AC mRNA was remarkably increased by 119.9% On day 3 after shAQP5 transfection, while comparable MUC5AC protein changes were not found in SPC-A1 cells with flow cytometry analysis. These results indicate that vector-based shRNA could be used as a potential tool to inhibit the expression of AQP5. This is the first investigation providing evidence demonstrating the regulation of the mucin gene by AQP5 gene silencing.     

Selective down-regulation of aquaporin-1 in salivary glands in primary Sjögren's syndrome

Salivary and lacrimal gland secretions are reduced in primary Sj?gren's syndrome (pSS). Aquaporins (AQPs) are involved in transmembrane water transport, and different isoforms show specific cellular and subcellular distributions in salivary and lacrimal glands. Changes in expression of AQP molecules have therefore been suggested to contribute to the glandular dysfunction in pSS. AQP-5 is present in the apical membrane of acinar cells, where it mediates fluid outflow; however, we have recently shown that its expression is not altered in pSS. We therefore studied whether expression of other isoforms of AQP would be altered in pSS. Using high-resolution confocal microscopy, we determined the distribution of AQP-1 and AQP-3 in labial salivary gland biopsies from 11 patients with pSS and 9 healthy controls. AQP-1 is present in myoepithelial cells surrounding acini, and its expression in these cells was decreased by 38% in pSS glands. By contrast, expression of AQP-1 in endothelial cells of nonfenestrated capillaries was not altered in pSS. AQP-3 was expressed in the basolateral membrane of acinar epithelial cells, and its expression was not altered in disease. We therefore conclude that AQP-1 expression in myoepithelial cells is selectively down-regulated in pSS and that myoepithelial cell dysfunction may play a crucial role in the pathology of this disease.     

Cellular localization of aquaporins along the secretory pathway of the lactating bovine mammary gland: An immunohistochemical study

In this study we examined the cellular localization of aquaporins (AQPs) along the secretory pathway of actively lactating bovine mammary glands using immunohistochemistry. Mammary tissues examined included secretory ducts and acini, gland cisterns, teats, stromal and adipose tissues. Aquaporin 1 (AQP1) was localized in capillary endothelia throughout the mammary gland in addition to myoepithelial cells underlying teat duct epithelia. AQP2 and AQP6 were not detected and AQP9 was found only in leukocytes. AQP3 and AQP4 were observed in selected epithelial cells in the teat, cistern and secretory tubuloalveoli. AQP5 immunopositivity was prominent in the cistern. AQP3 and AQP7 were found in smooth muscle bundles in the teat, secretory epithelial cells and duct epithelial cells. These immunohistochemical findings support a functional role for aquaporins in the transport of water and small solutes across endothelial and epithelial barriers in the mammary gland and in the production and secretion of milk.     

Altered aquaporin expression in glaucoma eyes

Aquaporins (AQP) are channels in the cell membrane that mainly facilitate a passive transport of water. In the eye, AQPs are expressed in the ciliary body and retina and may contribute to the pathogenesis of glaucoma and optic neuropathy. We investigated the expression of AQP1, AQP3, AQP4, AQP5, AQP7 and AQP9 in human glaucoma eyes compared with normal eyes. Nine glaucoma eyes were examined. Of these, three eyes were diagnosed with primary open angle glaucoma; three eyes had neovascular glaucoma; and three eyes had chronic angle‐closure glaucoma. Six eyes with normal intraocular pressure and without glaucoma were used as control. Immunohistochemistry was performed using antibodies against AQP1, AQP3, AQP4, AQP5, AQP7 and AQP9. For each specimen, optical densities of immunoprecipitates were measured using Photoshop and the staining intensities were calculated. Immunostaining showed labelling of AQP7 and AQP9 in the nonpigmented ciliary epithelium and the staining intensities were significantly decreased in glaucoma eyes (p = 0.003; p = 0.018). AQP7 expression in the Müller cell endfeet was increased (p = 0.046), and AQP9 labelling of the retinal ganglion cells (RGC) showed decreased intensity (p = 0.037). No difference in AQP1, AQP4 and AQP9 expression was found in the optic nerve fibres. This study is the first investigating AQPs in human glaucoma eyes. We found a reduced expression of AQP9 in the retinal ganglion cells of glaucoma eyes. Glaucoma also induced increased AQP7 expression in the Müller cell endfeet. In the ciliary body of glaucoma eyes, the expression of AQP7 and AQP9 was reduced. Therefore, the expression of AQPs seems to play a role in glaucoma.     

Further evidence for AQP8 expression in the myoepithelium of rat submandibular and parotid glands

Previously (Wellner et al., Pflugers Arch 441:49–56, 2000) we suggested that the localization of the aquaporins (AQPs) AQP5 and AQP8 in the apical and basolateral membranes of rat submandibular gland (SMG) acinar cells, respectively, provides for transcellular water flow during saliva formation. While the localization of AQP5 in this gland has been verified in several laboratories, there have been differing reports regarding AQP8 localization. Other investigators subsequently reported that AQP8 is not expressed in the acinar or ductal cells of the major salivary glands of the rat, but in the myoepithelium of each gland. Thus, we have carried out additional studies: (1) to reassess the localization of AQP8 in the rat SMG and (2) to assess the localization of AQP8 in the rat parotid gland (PG). Initially, we compared the localizations of AQP8 with recognized basolateral markers in acinar cells [the Na⁺,K⁺-ATPase and the Na⁺–K⁺–2Cl^– cotransporter (NKCC1)]. Our results indicated that Na⁺,K⁺-ATPase localized in both the basal and lateral membranes of rat SMG acinar cells, whereas AQP8 was detected only in the basal regions of the acini. In the rat PG, AQP8 was invested near intercalated ducts and adjacent acini, whereas NKCC1 localized in the basolateral membranes of acinar cells. As these results were suggestive of myoepithelial localization in both glands, we compared AQP8 localization with the localization of smooth muscle actin, a myoepithelial marker. We found that AQP8 and smooth muscle actin colocalized in both the rat SMG and PG, providing additional strong support for a myoepithelial localization of AQP8. Thus, in agreement with an earlier report by other investigators (Elkjaer et al., Am J Physiol Renal Physiol 281:F1047–F1057, 2001), we report that AQP8 is expressed in the myoepithelial cells, but not in the acinar cells, of both the rat SMG and PG.     

Chrysotile asbestos inhalation induces tritiated thymidine incorporation by epithelial cells of distal bronchioles

Previous studies in a rat model of asbestosis have demonstrated increased incorporation of tritiated thymidine by bronchiolar and alveolar epithelial cells 19 to 72 h after a single, 5-h exposure to chrysotile asbestos. This increase in thymidine labeling occurred at the first alveolar duct bifurcations, where terminal bronchioles end and where asbestos deposition is most concentrated. To determine whether airways more proximal than the terminal bronchioles exhibit a similar type of proliferative response to asbestos, incorporation of tritiated thymidine by airway epithelial cells was determined by light microscopic autoradiography. Incorporation by the epithelium in regions of the trachea, mainstem bronchi, and bronchioles was measured in lung tissue from sham-exposed and chrysotile asbestos-exposed rats, zero and 33 h after exposure. Sham-exposed animals and those studied immediately after exposure exhibited no increases in tritiated thymidine incorporation at any airway level. Tritiated thymidine incorporation by epithelial cells of bronchioles in peripheral regions of the lungs was significantly increased, as much as 20-fold, 33 h after chrysotile exposure. In the same asbestos-exposed animals, epithelial cells of the trachea, the bronchi, and the larger bronchioles did not exhibit increased cell labeling. The fact that asbestos was deposited throughout all airway levels, yet increased thymidine incorporation is observed primarily in the peripheral bronchiolar regions, raises interesting questions regarding the mechanisms of asbestos-induced cell proliferation.     

Characterization of the cell of origin and propagation potential of the fibroblast growth factor 9‐induced mouse model of lung adenocarcinoma

Fibroblast growth factor 9 (FGF9) is essential for lung development and is highly expressed in a subset of human lung adenocarcinomas. We recently described a mouse model in which FGF9 expression in the lung epithelium caused proliferation of the airway epithelium at the terminal bronchioles and led to rapid development of adenocarcinoma. Here, we used this model to characterize the effects of prolonged FGF9 induction on the proximal and distal lung epithelia, and examined the propagation potential of FGF9‐induced lung tumours. We showed that prolonged FGF9 over‐expression in the lung resulted in the development of adenocarcinomas arising from both alveolar type II and airway secretory cells in the lung parenchyma and airways, respectively. We found that tumour cells harboured tumour‐propagating cells that were able to form secondary tumours in recipient mice, regardless of FGF9 expression. However, the highest degree of tumour propagation was observed when unfractionated tumour cells were co‐administered with autologous, tumour‐associated mesenchymal cells. Although the initiation of lung adenocarcinomas was dependent on activation of the FGF9–FGF receptor 3 (FGFR3) signalling axis, maintenance and propagation of the tumour was independent of this signalling. Activation of an alternative FGF–FGFR axis and the interaction with tumour stromal cells is likely to be responsible for the development of this independence. This study demonstrates the complex role of FGF–FGFR signalling in the initiation, growth and propagation of lung cancer. Our findings suggest that analysing the expressions of FGF–FGFRs in human lung cancer will be a useful tool for guiding customized therapy. Copyright © 2014 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.     

Divergent expression and localization of aquaporin 5, an exocrine-type water channel,in the submandibular gland of Sprague-Dawley rats

By Western blot analysis, the expression level of aquaporin (AQP) 5 in the submandibular gland (SMG) was found to be different among individual rats of the Sprague-Dawley (SD) strain. Such differences were observed for AQP5 but not for AQP1 and consequently the SD strain was divided into two groups, one expressing a high level of AQP5 and the other a low one. The difference in average intensity of expression between the two groups was more than twofold. Immunohistochemical analysis of the SMG demonstrated that the AQP5 protein was localized in the basal and apical/lateral plasma membrane of acinar cells in rats expressing the high level of AQP5. In the rat expressing the low level, however, this channel protein was localized strongly in the apical/lateral plasma membrane, but only very weakly in the basal membrane of the acinar cells. Such a diverse localization of AQP5 was confirmed by Western blotting as well. Breeding between brother and sister was repeated for two times within high expressers and low expressers to obtain the third generation progenies (F2); the AQP5 level of the SMG in the third generation (F2 rats) from high expressers was significantly higher than the F2 from low expressers. Our present study suggests the existence of genetic variation in the expression of a water channel protein, AQP5, in rats.     

Tracheobronchial epithelium in the adult rhesus monkey: A quantitative histochemical and ultrastructural study

Previous studies of the intrapulmo-nary conducting airways of sheep and rabbit have demonstrated marked diversity in the epithelial populations lining them. Because studies of trachea and centriaci-nar regions of macaque monkeys suggested that primates may be even more diverse, the present study was designed to characterize the epithelial population throughout the airway tree of one primate species, the rhesus monkey. Trachea and intrapulmonary airways of the right cranial and middle lobes of glutaraldehyde/ paraformaldehyde-infused lungs of five adult rhesus monkeys were microdissected following the axial pathway. Each branch was assigned a binary number indicating its specific location within the tree. The trachea and six generations of intrapulmonary airway from the right cranial lobe were evaluated for ultrastructure and quantitative histology as were those of the right middle lobe for quantitative carbohydrate histochemistry. Four cell types were identified throughout the tree: ciliated, mucous goblet, small mucous granule, and basal. The tallest epithelium lined the trachea; the shortest, the respiratory bronchiole. The most cells per unit length of basement membrane were in proximal intrapulmonary bronchi; the least, in the respiratory bronchiole. The nonciliated bronchiolar epithelial or Clara cell was restricted to respiratory bronchioles. Sulfomucins were present in the vast majority of surface goblet cells in the trachea and proximal bronchi. In proximal bronchi, neutral glycoconjugates predominated in glands and acidic glycoconjugates in surface epithelium. In terminal and respiratory bronchioles the ratio of acidic gly-coconjugate to neutral glycoconjugate equaled that in proximal bronchi, although glands were not present. Sulfomucins were minimal in terminal airways. We conclude that the characteristics of the epithelial lining of the mammalian tracheobronchial airway tree are very species-specific. The lining of the rhesus monkey does not have the diversity in cell types in different airway generations observed in sheep and rabbit. Also, the populations lining these airways in the rhesus are very different from either the sheep or rabbit in number, proportions of different cell types, glycoconjugate content, and distribution of specific cell types.     

Modifying the NH2 and COOH termini of aquaporin-5: effects on localization in polarized epithelial cells

To reengineer polarized epithelial cell functions directly in situ, or ex vivo in the fabrication of an artificial organ, it is necessary to understand mechanisms that account for polarized membrane sorting. We have used the aquaporins (AQPs), a family of homotetrameric water channel proteins, as model membrane proteins for this purpose. AQP monomers contain six transmembrane-spanning domains linked by five interconnecting loops, with the NH2 and COOH termini residing in the cytosol. AQP5 is localized in the apical membranes of several different epithelia in vivo, and in stably transfected MDCK-II cells grown as a polarized monolayer. We wished to identify a structural region(s) within rat AQP5 (rAQP5) important for apical localization, and to study the MDCK-II cell localization of rAQP5s modified in either their NH2 or COOH terminus. We show that the NH2- terminal region does not play a major role in apical localization as deletion of the NH2 terminus produced a modified rAQP5 construct (AQP5-NT(del)) that was stably expressed and localized primarily to the apical membranes of MDCK-II cells. Attachment of a FLAG epitope to the NH2 terminus of AQP5 (AQP5(flag) construct) also did not perturb apical localization. In addition, we found that the exchange of NH2-terminal regions between rAQP5 and human AQP1 (hAQP1; a nonpolarized AQP isoform) produced a modified rAQP5 construct (AQP5-1NT) and a modified hAQP1 construct (AQP1-5NT), each of which localized as the parental AQP (apically, and to both apical and basolateral membranes, respectively). In contrast, we found that deletion of the COOH terminus resulted in a modified rAQP5 construct (AQP5-CT(del)) that was unstably expressed and localized to intracellular site(s) in MDCK-II cells. Substitution of the COOH terminus of AQP1 with the COOH terminus of AQP5 also produced a construct (AQP1-5CT) transiently expressed in intracellular compartment(s). However, substitution of the COOH terminus of rAQP5 with the COOH terminus of hAQP1 produced a modified rAQP5 construct (AQP5-1CT) that was stably expressed and localized to basolateral membranes, suggesting the loss of an apical targeting/retention signal from rAQP5, the gain of a basolateral targeting/retention signal from hAQP1, or a combination of these two possibilities.     

Role of water channels in fluid transport studied by phenotype analysis of aquaporin knockout mice

Aquaporin-type water channels are expressed widely in mammalian tissues, particularly in the kidney, lung, eye and gastrointestinal tract. To define the role of aquaporins in organ physiology, we have generated and analysed transgenic mice lacking aquaporins (AQP) 1, 3, 4 and 5. Multiple phenotype abnormalities were found in the null mice. For example, in kidney, deletion of AQP1 or AQP3 produced marked polyuria whereas AQP4 deletion produced only a mild concentrating defect. Deletion of AQP5, the apical membrane water channel in the salivary gland, caused defective saliva production. Deletion of AQP1 or AQP5, water channels in lung endothelia and epithelia, resulted in a 90% decrease in airspace-capillary water permeability. In the brain, deletion of AQP4 conferred marked protection from brain swelling induced by acute water intoxication and ischaemic stroke. The general paradigm that has emerged from these phenotype studies is that aquaporins facilitate rapid near-isosmolar transepithelial fluid absorption/secretion, as well as rapid vectorial water movement driven by osmotic gradients. However, we have found many examples in which the tissue-specific expression of an aquaporin is not associated with any apparent phenotypic abnormality. The physiological data on aquaporin null mice suggest the utility of aquaporin blockers and aquaporin gene replacement in selected human diseases.