Identification and characterization of aquaporin-2 water channel mutations causing nephrogenic diabetes insipidus with partial vasopressin response

Congenital nephrogenic diabetes insipidus (NDI) is a rare disease caused most often by mutations in the vasopressin V2 receptor (AVPR2). We studied a family which included a female patient with NDI with symptoms dating from infancy. The patient responded to large doses of desmopressin (dDAVP) which decreased urine volume from 10 to 4 I/day. Neither the parents nor the three sisters were polyuric. The patient was found to be a compound heterozygote for two novel recessive point mutations in the aquaporin-2 (AQP2) gene: L22V in exon 1 and C181W in exon 3. Residue Cys181 in AQP2 is the site for inhibition of water permeation by mercurial compounds and is located near to the NPA motif conserved in all aquaporins. Osmotic water permeability (Pf) in Xenopus oocytes injected with cRNA encoding C181W-AQP2 was not increased over water control, while expression of L22V cRNA increased the Pf to approximately 60% of that for wild-type AQP2. Co-injection of the mutant cRNAs with the wild-type cRNA did not affect the function of the wild-type AQP2. Immunolocalization of AQP2-transfected CHO cells showed that the C181W mutant had an endoplasmic reticulum-like intracellular distribution, whereas L22V and wild-type AQP2 showed endosome and plasma membrane staining. Water permeability assays showed a high Pf in cells expressing wild-type and L22V AQP2. This study indicates that AQP2 mutations can confer partially responsive NDI.      

NH3 and NH 4 + permeability in aquaporin-expressing Xenopus oocytes

We have shown recently, in a yeast expression system, that some aquaporins are permeable to ammonia. In the present study, we expressed the mammalian aquaporins AQP8, AQP9, AQP3, AQP1 and a plant aquaporin TIP2;1 in Xenopus oocytes to study the transport of ammonia (NH₃) and ammonium (NH₄⁺) under open-circuit and voltage-clamped conditions. TIP2;1 was tested as the wild-type and in a mutated version (tip2;1) in which the water permeability is intact. When AQP8-, AQP9-, AQP3- and TIP2;1-expressing oocytes were placed in a well-stirred bathing medium of low buffer capacity, NH₃ permeability was evident from the acidification of the bathing medium; the effects observed with AQP1 and tip2;1 did not exceed that of native oocytes. AQP8, AQP9, AQP3, and TIP2;1 were permeable to larger amides, while AQP1 was not. Under voltage-clamp conditions, given sufficient NH₃, AQP8, AQP9, AQP3, and TIP2;1 supported inwards currents carried by NH₄⁺. This conductivity increased as a sigmoid function of external [NH₃]: for AQP8 at a bath pH (pH_e) of 6.5, the conductance was abolished, at pH_e 7.4 it was half maximal and at pH_e 7.8 it saturated. NH₄⁺ influx was associated with oocyte swelling. In comparison, native oocytes as well as AQP1 and tip2;1-expressing oocytes showed small currents that were associated with small and even negative volume changes. We conclude that AQP8, AQP9, AQP3, and TIP2;1, apart from being water channels, also support significant fluxes of NH₃. These aquaporins could support NH₄⁺ transport and have physiological implications for liver and kidney function.     

Influence of outer pore residue K533 on the inhibition of Kv1.4 potassium channels by n-alkyl sulphate anions

 We have previously shown that although n-octyl sulphate (OS^–) and n-dodecyl sulphate (DDS^–) anions had similar effects on the kinetics and activation voltage dependence of RCK1 (Kv1.1), RCK4 (Kv1.4) and Shaker B channels expressed in Xenopus oocytes, both compounds produced a large decrease in the maximum conductance of RCK4 channels while significantly increasing the conductance of RCK1 and Shaker B. We suggested that this channel-specific inhibition might depend on the nature of the amino-acid residue corresponding to position 533 in RCK4. We now present data on the effects of n-alkyl sulphates on an RCK4 mutant in which the wild-type lysine at position 533 was changed to the corresponding tyrosine residue in RCK1. At a concentration of 15 μM, DDS^– caused a 48% reduction in the wild-type current at 50 mV but a 32% increase in the mutant current. n-Hexyl sulphate and OS^– had similar differential effects. The activation and inactivation kinetics of the mutant current were still accelerated by n-alkyl sulphates and 15 μM DDS^– moved the conductance/voltage curves of both wild-type and mutant channels some 24 mV in the hyperpolarizing direction. The K533Y mutation thus had a selective effect on current inhibition by n-alkyl sulphates. Received: 6 April 1998 / Accepted: 18 May 1998     

Heteroligomerization of an Aquaporin-2 mutant with wild-type Aquaporin-2 and their misrouting to late endosomes/lysosomes explains dominant nephrogenic diabetes insipidus

Autosomal nephrogenic diabetes insipidus (NDI), a disease in which the kidney is unable to concentrate urine in response to vasopressin, is caused by mutations in the Aquaporin-2 (AQP2) gene. Analysis of a new family with dominant NDI revealed a single nucleotide deletion (727deltaG) in one AQP2 allele, which encoded an AQP2 mutant with an altered and extended C-terminal tail. When expressed in oocytes, the tetrameric AQP2-727deltaG was retained within the cell. When co-expressed, AQP2-727deltaG, but not a mutant in recessive NDI (AQP2-R187C), formed hetero-oligomers with wild-type (wt) AQP2 and reduced the water permeability of these oocytes, because of a reduced plasma membrane expression of wt-AQP2. Expressed in renal epithelial cells, AQP2-727deltaG predominantly localized to the basolateral membrane and late endosomes/lysosomes, whereas wt-AQP2 was expressed in the apical membrane. Upon co-expressing in these cells, wt-AQP2 and AQP2-727deltaG mainly co-localized to late endosomes/lysosomes. In conclusion, hetero-oligomerization of AQP2-727deltaG with wt-AQP2 and consequent mistargeting of this complex to late endosomes/lysosomes results in absence of AQP2 in the apical membrane, which can explain dominant NDI in this family. Together with other mutants in dominant NDI, our data reveal that a misrouting, instead of a lack of function, is a general mechanism for the 'loss of function' phenotype in dominant NDI and visualizes for the first time a mislocalization of a wild-type protein to late endosomes/lysosomes in polarized cells after oligomerization with a mutant protein.     

Studies on the topology of the renal type II NaPi-cotransporter

 The rat type II sodium/phosphate cotransporter (NaPi-2) is a 85- to 90-kDa glycosylated protein located at the proximal tubular brush border membrane. Hydropathy predictions suggest eight transmembrane domains (sTM) with a large glycosylated loop between sTM 3 and sTM 4. We have studied the membrane topology of NaPi-2 expressed in oocytes. A 33-amino-acid fragment containing the FLAG epitope was inserted into seven loops connecting the sTMs and into the NH₂- and COOH-ends of the protein. FLAG-antibody binding suggested that the loops connecting sTM 1 and sTM 2 as well as sTM 3 and sTM 4 are located extracellularly. Based on the lack of FLAG-antibody binding we suggest intracellular locations for the NH₂- and COOH-termini and the region connecting sTM 4 and sTM 5. Immunoprecipitation studies of in vitro translated protein also suggest that the NH₂-terminus is sited extracellularly. In immunohistochemical studies with NaPi-2-transfected MDCK cells, an interaction with NH₂- and COOH- terminal antipeptide antibodies could only be obtained after membrane permeabilization. The presented data are an experimental documentation of the intracellular location of the NH₂- and COOH-termini, and of the extracellular location of extracellular loops 1 and 2. Received: 30 November 1998 / Received after revision: 19 January 1999 / Accepted: 20 January 1999     

Aquaporin 6 is permeable to glycerol and urea

The passive water permeability (L_p) of AQP6 is activated by Hg²⁺. Our aim was to test if L_p was associated with a permeability to small hydrophilic molecules such as glycerol and urea. AQP6 was expressed in Xenopus laevis oocytes and activated by 0.3 mM of HgCl₂ in the bathing solution. HgCl₂ caused the oocytes to swell at a rate of about 0.3% min^–1. The L_p of AQP6 was determined from brief additions or removals of mannitol from the bathing solution, and compared to the L_p obtained from adding glycerol or urea. In paired experiments, L_{p (mannitol)} was 2.4±0.1, L_{p (glycerol)} 1.5±0.2, and L_{p (urea)} 0.7±0.1 (units: 10^–5 cm s^–1 osmol^–1; 14 oocytes); the latter was not different from L_ps obtained for native oocytes. The L_ps were independent of the Hg²⁺-induced swelling and of the magnitude of the osmotic challenge (–75 to +100 mosmol). Hg²⁺ stimulated the uptake of [¹⁴C]glycerol fivefold and [¹⁴C]urea twofold in AQP6-expressing oocytes. There were no significant uptakes in native oocytes nor in AQP1-expressing oocytes whether these were treated with HgCl₂ or not. We conclude that water, glycerol and urea share an aqueous pathway in AQP6.     

Evidence for a glycerol pathway through aquaporin 1 (CHIP28) channels

Permeabilities to glycerol and small non-electrolytes of three Aquaporin 1 CHIP (AQP1) water channels were measured in AQP1 cRNA-injected Xenopus laevis oocytes and in human AQP1 channels reconstituted in proteoliposomes. By an osmotic swelling assay, significant increases of ethylene glycol, glycerol and 1,3-propanediol apparent permeability coefficients (P_solutes) were found in oocytes expressing human, rat and frog AQP1. p-Chloromercuribenzene sulphonate (PCMBS) and CuSO₄ inhibited, by 95% and 58% respectively, apparent glycerol permeability (P _gly) in oocytes expressing human AQP1. pCMBS inhibition was reversed by -mercaptoethanol and CuSO₄ inhibition was partly reversed by the Cu²⁺-binding peptide Gly-Gly-His. Tritiated glycerol uptakes confirmed the augmented P _gly value of AQP1 cRNA-injected oocytes. In contrast, no increases of urea, meso-erythritol, D- or L-threitol, xylitol and mannitol uptakes were detected. Stopped-flow light scattering experiments performed with human AQP1 proteoliposomes also revealed a much greater increase of P _gly than did those with protein-free liposomes; the initial rate of proteoliposomes also swelling was inhibited by 96.2% with HgCl₂ and by 72.5% with CuSO₄. In AQP1 cRNA-injected oocytes and in proteoliposomes, the value of the glycerol reflection coefficient was 0.74–0.80, indicating that water and glycerol share the same pathway. All these results provide strong evidence that water and certain small solutes permeate the AQP1 channels expressed at the surface of X. laevis oocytes or reconstituted in proteoliposomes. The urea exclusion suggests that the selectivity of the AQP1 channels not only depends on the size of the solutes but probably also on their flexibility and their ability to form H-bonds.     

Repulsion between Lys258 and upstream arginines explains the missorting of the AQP2 mutant p.Glu258Lys in nephrogenic diabetes insipidus

Regulation of body water homeostasis occurs by the vasopressin‐dependent sorting of aquaporin‐2 (AQP2) water channels to and from the apical membrane of renal principal cells. Mutations in AQP2 cause autosomal nephrogenic diabetes insipidus (NDI), a disease that renders the kidney unresponsive to vasopressin, resulting in polyuria and polydipsia. The AQP2 mutant c.772G>A; p.Glu258Lys (AQP2–E258K) causes dominant NDI by oligomerizing with wild‐type AQP2 and missorting of this AQP2 complex to multivesicular bodies instead of the apical membrane. The motif causing this missorting of AQP2–E258K was identified here. Functional analyses and plasma membrane expression studies of truncation mutants in oocytes revealed that AQP2–E258K shortened to Leu259 is still intracellular retained. Alanine scanning and glutamic acid to arginine exchanges revealed increased function and plasma membrane expression for AQP2–E258K mutants with the following additional changes: Leu259Ala, Arg252Glu, Arg253Glu, or Arg252Ala–Arg254Ala, or for the AQP2 mutant p.Glu258Ala, indicating that the motif RRRxxxK₂₅₈L confers AQP2–E258K retention. Fusion of this motif to aquaporin‐1 also resulted in missorting of that water channel, indicating that this retention motif is transferable. In conclusion, our data reveal that the RRRxxxKL motif and repulsion between K258 and the arginine‐triplet within this motif are the primary cause of missorting of AQP2–E258K in NDI. Hum Mutat 30:1–10, 2009. © 2009 Wiley‐Liss, Inc.     

Cystic fibrosis transmembrane conductance regulator activates water conductance in Xenopus oocytes

 Multiple properties have been attributed to the cystic fibrosis transmembrane conductance regulator (CFTR), the gene product which is mutated in cystic fibrosis (CF). In this context it has been reported that CFTR transports water. In the present study we demonstrate that expression of wild-type CFTR (wtCFTR) in Xenopus oocytes and then stimulation by 3-isobutyl-1-methylxanthine (IBMX, 1 mmol/l) activates a Cl^–conductance and, in parallel, a water conductance, as measured by a volume increase gravimetrically. In water-injected control oocytes or oocytes expressing a mutant form of CFTR (G551D-CFTR) IBMX had very little effect on Cl^–conductance and no effect on water conductance. Phloretin (350 μmol/l) and p-chloromercuri-benzene sulphonate (pCMBS, 1 mmol/l) inhibited water transport but did not inhibit Cl^–currents when measured in double-electrode voltage-clamp experiments. In contrast, glibenclamide (100 μmol/l) inhibited wtCFTR Cl^–conductance but did not inhibit water conductance in IBMX-stimulated oocytes. Moreover, gravimetric and [¹⁴C]glycerol uptake measurements indicated enhanced glycerol uptake by wtCFTR-expressing oocytes after stimulation with IBMX. Enhanced glycerol uptake could be inhibited by phloretin and pCMBS but not by glibenclamide. Taken together, the data suggest that activation of wtCFTR by an increase of intracellular cAMP is paralleled by the activation of a gylcerol-permeable water conductance. Both water and Cl^–conductive pathways can be inhibited differentially. Thus, water permeation through wtCFTR probably occurs at a site of CFTR which is spatially apart from the domain responsible for Cl^–conductance, or CFTR might be a regulator of an endogenous water channel in oocytes. Received: 24 March 1997 / Received after revision and accepted: 16 June 1997     

H+ ion modulation of C-type inactivation of Shaker K+ channels

 The participation of an extracellular loop in C-type inactivation of voltage-gated K⁺ channels was investigated. A wild-type phenylalanine (at position 425) between the fifth putative transmembrane segment (S5) and the pore region of the Shaker K⁺ channel was mutated to a histidine and the functional consequences of protonating the imidizole group of the histidine were examined. C-type inactivation of both wild-type and mutant channels was sensitive to external pH over the range of 5.2–8. The pH dependence of wild-type channels was characterized by an apparent pK value of 5.0. The inactivation kinetics of F425H mutant channels had a pH dependence with a pK of 5.8 – in addition to the pH dependence of the wild-type channels. Moreover, at pH 7 and 8 the voltage dependence of C-type inactivation kinetics was manifest only in the F425H mutant channels. C-type inactivation in wild-type channels involves a chemical group with a low pK. Taken together, these results suggest that residues located in the extracellular S5-pore loop of the Shaker K⁺ channel participate in C-type inactivation. Received: 30 September 1998 / Received after revision: 8 January 1999 / Accepted: 18 January 1999     

Isometric and isotonic muscle properties as determinants of work loop power output

 The power output of rabbit latissimus dorsi muscle was calculated under isotonic conditions and during oscillatory work. Isotonic shortening studies yielded a maximum power output of 120 W·kg⁻¹ at a P/P ₀ of 0.4 compared to a maximum power output of 32 W·kg⁻¹ obtained using the work loop technique. This difference can largely be explained by comparing actual work loops with those constructed using force velocity (P/V) and isometric data. At low cycle frequencies, work loop power output is quite close to that predicted from P/V and isometric data. However, at higher frequencies other dynamic muscle properties appear to exert a more marked effect. Received: 24 October 1995 / Received after revision and accepted: 10 May 1996     

Endogenous protease-dependent replication of human influenza viruses in two MDCK cell lines

Summary.  Multi-cycle replication and plaque formation of influenza A and B viruses and cleavage activation of their hemagglutinin (HA) by an endogenous protease(s) were examined in two MDCK cell lines, MDCK(−) and MDCK(+). No exogenous trypsin was required for multi-cycle replication and plaque formation of all the influenza A viruses tested in the MDCK(+) cell, while those of the viruses in the MDCK(−) cell were completely trypsin-dependent. In both cell lines, on the other hand, influenza B viruses grew well in the absence of trypsin. The capability of multiple replication and plaque formation of the influenza viruses correlated with cleavage of the HA precursor (HA₀) to HA₁ and HA₂, indicating that both cell lines express an HA activating endoprotease(s); that of the MDCK(+) cell activates the HA of influenza A and B viruses, and that of the MDCK(−) cell does only the HA of influenza B virus. Furthermore, the protease of the MDCK(+) cell was strongly suggested to be present on the cell surface and a serine protease. The MDCK(+) cell would be useful for isolation of influenza viruses from clinical specimens and for screening of protease inhibitors for anti-influenza virus drugs. Received April 9, 1998. Accepted May 22, 1998     

A chimeric connexin forming gap junction hemichannels

 Connexins are the subunits of gap junction channels which connect neighboring cells. With the exception of lens connexins, they usually do not form open hemichannels in the cell membrane of single cells. Here we describe a chimeric connexin consisting of cx32 where the first extracellular loop sequence is replaced by the corresponding cx43 sequence. This chimera, cx32E₁43, forms conventional gap junction channels in the paired oocyte assay. In addition cx32E₁43 induces a membrane conductance in single oocytes. This membrane conductance is voltage dependent and is similarly sensitive to CO₂ as are gap junction channels formed by the chimera or by wild-type cx32. These data suggest that cx32E₁43 forms patent hemichannels in the plasma membrane of single oocytes. This conclusion is further supported by the observation that oocytes expressing cx32E₁43 take up from the bath medium tracer molecules known to pass through gap junction channels. Received: 13 November 1996 / Received after revision: 13 December 1996 / Accepted: 16 December 1996     

Aggravated chronic brain injury after focal cerebral ischemia in aquaporin-4-deficient mice

The water channel aquaporin-4 (AQP4) is important in brain water homeostasis, and is also involved in astrocyte growth and glial scar formation. It has been reported that AQP4 deficiency attenuates acute ischemic brain injury as a result of reducing cytotoxic edema. Here, we determined whether AQP4 deficiency influences chronic brain injury after focal cerebral ischemia induced by 30 min of middle cerebral artery occlusion (MCAO). AQP4^−/− mice exhibited a lower survival rate and less body weight gain than wild-type mice, but their neurological deficits were similar to wild-type mice during 35 days after MCAO. At 35 days after MCAO, AQP4^−/− mice showed more severe brain atrophy and cavity formation in the ischemic hemisphere as well as more neuronal loss in the hippocampus. Furthermore, astrocyte proliferation and glial scar formation were impaired in AQP4^−/− mice. Therefore, AQP4 deficiency complicated by astrocyte dysfunction aggravates chronic brain injury after focal cerebral ischemia, suggesting that AQP4 may be important in the chronic phase of the post-ischemic recovery process.     

Missorting of the Aquaporin-2 mutant E258K to multivesicular bodies/lysosomes in dominant NDI is associated with its monoubiquitination and increased phosphorylation by PKC but is due to the loss of E258

To stimulate renal water reabsorption, vasopressin induces phosphorylation of Aquaporin-2 (AQP2) water channels at S256 and their redistribution from vesicles to the apical membrane, whereas vasopressin removal results in AQP2 ubiquitination at K270 and its internalization to multivesicular bodies (MVB). AQP2-E258K causes dominant nephrogenic diabetes insipidus (NDI), but its subcellular location is unclear, and the molecular reason for its involvement in dominant NDI is unknown. To unravel these, AQP2-E258K was studied in transfected polarized Madin–Darby canine kidney (MDCK) cells. In MDCK cells, AQP2-E258K mainly localized to MVB/lysosomes (Lys). Upon coexpression, wild-type (wt) AQP2 and AQP2-E258K formed multimers, which also localized to MVB/Lys, independent of forskolin stimulation. Orthophosphate labeling revealed that forskolin increased phosphorylation of wt-AQP2 and AQP2-E258K but not AQP2-S256A, indicating that the E258K mutation does not interfere with the AQP2 phosphorylation at S256. In contrast to wt-AQP2 but consistent with the introduced protein kinase C (PKC) consensus site, AQP2-E258K was phosphorylated by phorbol esters. Besides the 29-kDa band, however, an additional band of about 35 kDa was observed for AQP2-E258K only, which represented AQP2-E258K uniquely monoubiquitinated at K228 only. Analysis of several mutants interfering with AQP2-E258K phosphorylation, and/or ubiquitination, however, revealed that the MVB/lysosomal sorting of AQP2-E258K occurred independent of its monoubiquitination or phosphorylation by PKC. Instead, our data reveal that the loss of the E258 in AQP2-E258K is fundamental to its missorting to MVB/Lys and indicate that this amino acid has an important role in the proper structure formation of the C-terminal tail of AQP2.     

Small-volume and rapid extracellular solution exchange around Xenopus oocytes during voltage-clamp recordings

 A novel method for micro extracellular perfusion of Xenopus oocytes has been designed in order to minimise the amount of test solution required for drug applications during two-microelectrode voltage-clamp experiments. Voltage-clamp experiments on oocytes are performed in a glass-covered microbath without continuous perfusion. The microelectrodes access the oocytes via two small openings in the glass cover. Test solutions are applied to a funnel at the chamber inflow and the chamber volume is subsequently exchanged by operating a suction pump connected to the chamber outflow. Only 50 μl of drug- or neurotransmitter-containing solution is required for bath application. In addition, the new ”funnel application technique” enables quick and timed applications of drugs or neurotransmitters to Xenopus oocytes within 200–400 ms. Received: 16 December 1997 / Received after revision and accepted: 11 March 1998     

The 42K protein of rice dwarf virus is a post-translational cleavage product of the 46K outer capsid protein

Summary.  The outer capsid protein (P8) heterogeneity of rice dwarf virus (RDV) exists not only in purified virus particles, but also in RDV-infected rice, transgenic rice expressing P8, E. coli expression of P8 product and the in vitro translation products of S8. N-terminal amino acid sequencing revealed that P8 is a cleavage product of P8′. The cleavage occurs specifically at the residues of Asp³⁶² and Pro³⁶³. The function of the proteolytic processing is unknown. Received July 26, 1998 Accepted April 3, 1998