Identification and functional analysis of a splice variant of mouse sodium-dependent phosphate transporter Npt2c.

Mutations in the SLC34A3 gene, a sodium-dependent inorganic phosphate (Pi) cotransporter, also referred to as NaPi IIc, causes hereditary hypophosphatemic rickets with hypercalciuria (HHRH), an autosomal recessive disorder. In human and rodent, NaPi IIc is mainly localized in the apical membrane of renal proximal tubular cells. In this study, we identified mouse NaPi IIc variant (Npt2c-v1) that lacks the part of the exon 3 sequence that includes the assumed translation initiation site of Npt2c. Microinjection of mouse Npt2c-v1 cRNA into Xenopus oocytes demonstrated that Npt2c-v1 showed sodium-dependent Pi cotransport activity. The characterization of pH dependency showed activation at extracellular alkaline-pH. Furthermore, Npt2c-v1 mediated Pi transport activity was significantly higher at any pH value than those of Npt2c. In an in vitro study, the localization of the Npt2c-v1 protein was detected in the apical membrane in opossum kidney cells. The expression of Npt2c-v1 mRNA was detected in the heart, spleen, testis, uterus, placenta, femur, cerebellum, hippocampus, diencephalon and brain stem of mouse. Using mouse bone primary cultured cells, we showed the expression of Npt2c-v1 mRNA. In addition, the Npt2c protein was detected in the spermatozoa head. Thus, Npt2c-v1 was expressed in extra-renal tissues such as epididymal spermatozoa and may function as a sodium-dependent phosphate transporter.

Npt2a and Npt2c in mice play distinct and synergistic roles in inorganic phosphate metabolism and skeletal development.

Hereditary hypophosphatemic rickets with hypercalciuria (HHRH) is a rare autosomal recessively inherited disorder, characterized by hypophosphatemia, short stature, rickets and/or osteomalacia, and secondary absorptive hypercalciuria. HHRH is caused by a defect in the sodium-dependent phosphate transporter (NaPi-IIc/Npt2c/NPT2c), which was thought to have only a minor role in renal phosphate (P(i)) reabsorption in adult mice. In fact, mice that are null for Npt2c (Npt2c(-/-)) show no evidence for renal phosphate wasting when maintained on a diet with a normal phosphate content. To obtain insights and the relative importance of Npt2a and Npt2c, we now studied Npt2a(-/-)Npt2c(+/+), Npt2a(+/-)Npt2c(-/-), and Npt2a(-/-)Npt2c(-/-) double-knockout (DKO). DKO mice exhibited severe hypophosphatemia, hypercalciuria, and rickets. These findings are different from those in Npt2a KO mice that show only a mild phosphate and bone phenotype that improve over time and from the findings in Npt2c KO mice that show no apparent abnormality in the regulation of phosphate homeostasis. Because of the nonredundant roles of Npt2a and Npt2c, DKO animals showed a more pronounced reduction in P(i) transport activity in the brush-border membrane of renal tubular cells than that in the mice with the single-gene ablations. A high-P(i) diet after weaning rescued plasma phosphate levels and the bone phenotype in DKO mice. Our findings thus showed in mice that Npt2a and Npt2c have independent roles in the regulation of plasma P(i) and bone mineralization.

Type IIc sodium-dependent phosphate transporter regulates calcium metabolism.

Primary renal inorganic phosphate (Pi) wasting leads to hypophosphatemia, which is associated with skeletal mineralization defects. In humans, mutations in the gene encoding the type IIc sodium-dependent phosphate transporter lead to hereditary hypophophatemic rickets with hypercalciuria, but whether Pi wasting directly causes the bone disorder is unknown. Here, we generated Npt2c-null mice to define the contribution of Npt2c to Pi homeostasis and to bone abnormalities. Homozygous mutants (Npt2c(-/-)) exhibited hypercalcemia, hypercalciuria, and elevated plasma 1,25-dihydroxyvitamin D(3) levels, but they did not develop hypophosphatemia, hyperphosphaturia, renal calcification, rickets, or osteomalacia. The increased levels of 1,25-dihydroxyvitamin D(3) in Npt2c(-/-) mice compared with age-matched Npt2c(+/+) mice may be the result of reduced catabolism, because we observed significantly reduced expression of renal 25-hydroxyvitamin D-24-hydroxylase mRNA but no change in 1alpha-hydroxylase mRNA levels. Enhanced intestinal absorption of calcium (Ca) contributed to the hypercalcemia and increased urinary Ca excretion. Furthermore, plasma levels of the phosphaturic protein fibroblast growth factor 23 were significantly decreased in Npt2c(-/-) mice. Sodium-dependent Pi co-transport at the renal brush border membrane, however, was not different among Npt2c(+/+), Npt2c(+/-), and Npt2c(-/-) mice. In summary, these data suggest that Npt2c maintains normal Ca metabolism, in part by modulating the vitamin D/fibroblast growth factor 23 axis.

Correlation between hyperphosphatemia and type II Na-Pi cotransporter activity in klotho mice.

Recent studies have demonstrated that klotho protein plays a role in calcium/phosphate homeostasis. The goal of the present study was to investigate the regulation of Na-P(i) cotransporters in klotho mutant (kl/kl) mice. The kl/kl mice displayed hyperphosphatemia, high plasma 1,25(OH)(2)D(3) levels, increased activity of the renal and intestinal sodium-dependent P(i) cotransporters, and increased levels of the type IIa, type IIb, and type IIc transporter proteins compared with wild-type mice. Interestingly, transcript levels of the type IIa/type IIc transporter mRNA abundance, but not transcripts levels of type IIb transporter mRNA, were markedly decreased in kl/kl mice compared with wild-type mice. Furthermore, plasma fibroblast growth factor 23 (FGF23) levels were 150-fold higher in kl/kl mice than in wild-type mice. Feeding of a low-P(i) diet induced the expression of klotho protein and decreased plasma FGF23 levels in kl/kl mice, whereas colchicine treatment experiments revealed evidence of abnormal membrane trafficking of the type IIa transporter in kl/kl mice. Finally, feeding of a low-P(i) diet resulted in increased type IIa Na-P(i) cotransporter protein in the apical membrane in the wild-type mice, but not in kl/kl mice. These results indicate that hyperphosphatemia in klotho mice is due to dysregulation of expression and trafficking of the renal type IIa/IIc transporters rather than to intestinal P(i) uptake.

Parathyroid hormone-dependent endocytosis of renal type IIc Na-Pi cotransporter.

Hereditary hypophosphatemic rickets with hypercalciuria results from mutations of the renal type IIc Na-P(i) cotransporter gene, suggesting that the type IIc transporter plays a prominent role in renal phosphate handling. The goal of the present study was to investigate the regulation of the type IIc Na-P(i) cotransporter by parathyroid hormone (PTH). Type IIc Na-P(i) cotransporter levels were markedly increased in thyroparathyroidectomized (TPTX) rats. Four hours after administration of PTH, type IIc transporter protein levels were markedly decreased in the apical membrane fraction but recovered to baseline levels at 24 h. Immunohistochemical analyses demonstrated the presence of the type IIc transporter in the apical membrane and subapical compartments in the proximal tubular cells in TPTX animals. After administration of PTH, the intensity of immunoreactive signals in apical and subapical type IIc transporter decreased in the renal proximal tubular cells in TPTX rats. Colchicine completely blocked the internalization of the type IIc transporter. In addition, leupeptin prevented the PTH-mediated degradation of the type IIa transporter in lysosomes but had no effect on PTH-mediated degradation of the lysosomal type IIc transporter. In PTH-treated TPTX rats, the internalization of the type IIc transporter occurred after administration of PTH(1-34) (PKA and PKC activator) or PTH(3-34) (PKC activator). Thus the present study demonstrated that PTH is a major hormonal regulator of the type IIc Na-P(i) cotransporter in renal proximal tubules.