Effects of chemical chaperones on partially retarded NaCl cotransporter mutants associated with Gitelman's syndrome in a mouse cortical collecting duct cell line.

BACKGROUND: Epithelial cells lining the distal convoluted tubule express the thiazide-sensitive Na-Cl cotransporter (NCC) that is responsible for the reabsorption of 5-10% of the filtered load of Na(+) and Cl(-). Mutations in NCC cause the autosomal recessive renal disorder Gitelman's syndrome (GS). GS mutations give rise to mutant transporters that are either fully (class I) or partially (class II) retarded. Recent evidence indicates that class II mutations do not alter the intrinsic transport activity of NCC. These findings suggest that in GS caused by class II NCC mutations, pharmacological chaperones may be useful in treatment. METHODS: Initial attempts using 4-phenylbutyrate and glycerol to increase Na(+) uptake in Xenopus laevis oocytes expressing the class II mutant L215P were unsuccessful. To study the effect of the chaperones in a more physiological setting, we next expressed hNCC in the polarized epithelial cell line of distal tubular origin, mpkCCD. RESULTS: mpkCCD cells readily expressed the class II mutant R955Q, but not the class I mutant G741R. Wild-type hNCC was predominantly present in the approximately 120-1403 kD complex glycosylated form. In contrast, the R955Q mutant was predominantly present in a lower molecular weight form of approximately 100 kD. Pretreatment of R955Q expressing cells with 4-phenylbutyrate (5 mM, 16 h), but not thapsigargin (1 microM, 90 min), dimethyl sulfoxide (1%, 16 h) or glycerol (4%, 16 h), increased the expression of the complex glycosylated form and in parallel the number of hNCC positive cells. CONCLUSIONS: Taken together, the data indicate that 4-phenylbutyrate is a promising candidate for rescuing partially retarded but otherwise functional class II GS mutants.

Functional expression of the human thiazide-sensitive NaCl cotransporter in Madin-Darby canine kidney cells.

The thiazide-sensitive Na(+)-Cl(-) cotransporter (NCC), which is expressed on the apical membrane of epithelial cells lining the distal convoluted tubule, is responsible for the reabsorption of 5% to 10% of filtered Na(+) and Cl(-). To date, functional studies on the structural and regulatory requirements for localized trafficking and ion-transporting activity of NCC have been hampered by lack of a suitable cell system expressing this cotransporter. Reported here is the functional expression of human NCC (hNCC) in a polarized mammalian cell of renal origin-that is, the high-resistance Madin-Darby canine kidney (MDCK) cell. Western blot testing revealed that the cells predominantly expressed the complex glycosylated (approximately 140 kD) form of hNCC. hNCC was present primarily in the apical part of the cell. The functionality of hNCC was demonstrated by the gain of thiazide-sensitive Na(+) uptake and transepithelial transport activity. Na(+) uptake was significantly increased after short-term (15 min) treatment with forskolin, whereas cyclic guanosine monophosphate, wortmannin, phorbol 12-myriatate 13-acetate, and staurosporine were without effect. This indicates that hNCC activity is regulated through cyclic adenosine monophosphate, rather than via cyclic guanosine monophosphate, phospho-inositide 3-kinases or protein kinase C. Aldosterone did not alter Na(+) uptake in the short term (15 min) but significantly increased the transport activity in the long term (16 h). The latter effect of aldosterone was due to an effect on the cytomegalovirus promoter/enhancer driving the expression of hNCC. hNCC-MDCK cells are a good model for the study of the regulation of apical trafficking and ion-transporting activity of hNCC.

Genetic renal disorders with hypomagnesemia and hypocalciuria.

The combination of hypomagnesemia and hypocalciuria is the phenotypic signature of two distinct genetic renal tubular transport disorders: Gitelman's syndrome and autosomal dominant isolated renal magnesium wasting. In the past 5 years the genetic defects underlying these disorders have been elucidated through positional candidate cloning approaches. The defective proteins involved in both diseases are located within the distal convoluted tubule (DCT), a segment of the nephron known to play an important role in active magnesium reabsorption in the nephron. The introduction outlines the magnesium handling in the body in general and, in particular, in the kidney, followed by a detailed discussion of Gitelman's syndrome and isolated renal magnesium wasting, including the clinical and biochemical symptoms, genetic aspects and pathophysiology.

Dominant isolated renal magnesium loss is caused by misrouting of the Na+,K+-ATPase gamma-subunit.

Hereditary primary hypomagnesemia comprises a clinically and genetically heterogeneous group of disorders in which hypomagnesemia is due to either renal or intestinal Mg(2+) wasting. These disorders share the general symptoms of hypomagnesemia, tetany and epileptiformic convulsions, and often include secondary or associated disturbances in calcium excretion. In a large Dutch family with autosomal dominant renal hypomagnesemia, associated with hypocalciuria, we mapped the disease locus to a 5.6-cM region on chromosome 11q23. After candidate screening, we identified a heterozygous mutation in the FXYD2 gene, encoding the Na(+),K(+)-ATPase gamma-subunit, cosegregating with the patients of this family, which was not found in 132 control chromosomes. The mutation leads to a G41R substitution, introducing a charged amino acid residue in the predicted transmembrane region of the gamma-subunit protein. Expression studies in insect Sf9 and COS-1 cells showed that the mutant gamma-subunit protein was incorrectly routed and accumulated in perinuclear structures. In addition to disturbed routing of the G41R mutant, Western blot analysis of Xenopus oocytes expressing wild-type or mutant gamma-subunit showed mutant gamma-subunit lacking a posttranslational modification. Finally, we investigated two individuals lacking one copy of the FXYD2 gene and found their serum Mg(2+) levels to be within the normal range. We conclude that the arrest of mutant gamma-subunit in distinct intracellular structures is associated with aberrant posttranslational processing and that the G41R mutation causes dominant renal hypomagnesemia associated with hypocalciuria through a dominant negative mechanism.

The structural unit of the thiazide-sensitive NaCl cotransporter is a homodimer.

The thiazide-sensitive NaCl cotransporter (NCC) is responsible for the reabsorption of 5% of the filtered load of NaCl in the kidney. Mutations in NCC cause Gitelman syndrome. To gain insight into its regulation, detailed information on the structural composition of its functional unit is essential. Western blot analysis of total membranes of Xenopus laevis oocytes heterologously expressing FLAG-tagged NCC revealed the presence of both complex-(140-kDa) and core (100-kDa)-glycosylated monomers and a broad band of high molecular mass (250-350-kDa) complexes. Chemical cross-linking with dithiobispropionimidate eliminated the low molecular weight bands and increased the intensity of the high molecular weight bands, indicating that NCC is present in multimeric complexes. Co-expression of HA- and FLAG-tagged NCC followed by co-immunoprecipitation demonstrated that these multimers contained at least two complex-glycosylated NCC proteins. The dimeric nature of the multimers was further substantiated by sucrose gradient centrifugation yielding a peak of approximately 310 kDa. A concatameric construct of two NCC polyproteins exhibited significant 22Na+ uptake, indicating that the transporter is functional as a homodimer. A concatamer of partially retarded G980R- and wild type (wt)-NCC displayed normal Na+ transport. This demonstrates that G980R-NCC, provided that it reaches the surface, is fully active and that wt-NCC is dominant in its association with this mutant. Conversely a concatamer of fully retarded G741R- and wt-NCC did not reach the cell surface, showing that wt-NCC is recessive in its association with this mutant. Oocytes co-expressing G741R- and wt-NCC did not show G741R staining at the plasma membrane, whereas Na+ transport was normal, indicating that wt-NCC dimerizes preferentially with itself. The results are discussed in relation to the recessive nature of NCC mutants in Gitelman syndrome.

Functional expression of mutations in the human NaCl cotransporter: evidence for impaired routing mechanisms in Gitelman's syndrome.

Gitelman's syndrome is an autosomal recessive renal tubular disorder characterized by hypokalemic metabolic alkalosis, hypomagnesemia, and hypocalciuria. This disorder results from mutations in the thiazide-sensitive NaCl cotransporter (NCC). To elucidate the functional implications of mutations associated with this disorder, metolazone-sensitive (22)Na(+) uptake, subcellular localization, and glycosidase-sensitive glycosylation of human NCC (hNCC) were determined in Xenopus laevis oocytes expressing FLAG-tagged wild-type or mutant hNCC. Injection of 10 ng of FLAG-tagged hNCC cRNA resulted in metolazone-sensitive (22)Na(+) uptake of 3.4 +/- 0.2 nmol Na(+)/oocyte per 2 h. Immunocytochemical analysis revealed sharp immunopositive staining at the plasma membrane. In agreement with this finding, a broad endoglycosidase H-insensitive band of 130 to 140 kD was present in Western blots of total membranes. The plasma membrane localization of this complex-glycosylated protein was confirmed by immunoblotting of purified plasma membranes. The mutants could be divided into two distinct classes. Class I mutants (G439S, T649R, and G741R) exhibited no significant metolazone-sensitive (22)Na(+) uptake. Immunopositive staining was present in a diffuse band just below the plasma membrane. This endoplasmic reticulum and/or pre-Golgi complex localization was further suggested by the complete absence of the endoglycosidase H-insensitive band. Class II mutants (L215P, F536L, R955Q, G980R, and C985Y) demonstrated significant metolazone-sensitive (22)Na(+) uptake, although uptake was significantly lower than that obtained with wild-type hNCC. The latter mutants could be detected at and below the oocyte plasma membrane, and immunoblotting revealed the characteristic complex-glycosylated bands. In conclusion, this study substantiates NCC processing defects as the underlying pathogenic mechanism in Gitelman's syndrome.