Differential effects of Npt2a gene ablation and X-linked Hyp mutation on renal expression of Npt2c.
about
SLC34A3 mutations in patients with hereditary hypophosphatemic rickets with hypercalciuria predict a key role for the sodium-phosphate cotransporter NaPi-IIc in maintaining phosphate homeostasisHereditary hypophosphatemic rickets with hypercalciuria is caused by mutations in the sodium-phosphate cotransporter gene SLC34A3.Interactions of the growth-related, type IIc renal sodium/phosphate cotransporter with PDZ proteinsIncreased bone volume and correction of HYP mouse hypophosphatemia in the Klotho/HYP mouse.Hypophosphatemia leads to rickets by impairing caspase-mediated apoptosis of hypertrophic chondrocytes.Phosphatonin washout in Hyp mice proximal tubules: evidence for posttranscriptional regulation.Renal control of calcium, phosphate, and magnesium homeostasisFibroblast growth factor 23 regulates renal 1,25-dihydroxyvitamin D and phosphate metabolism via the MAP kinase signaling pathway in Hyp miceThe wrickkened pathways of FGF23, MEPE and PHEX.Recent advances in renal phosphate transport.Activation of a non-cAMP/PKA signaling pathway downstream of the PTH/PTHrP receptor is essential for a sustained hypophosphatemic response to PTH infusion in male mice.A missense mutation in the sodium phosphate co-transporter Slc34a1 impairs phosphate homeostasis.A novel missense mutation in SLC34A3 that causes hereditary hypophosphatemic rickets with hypercalciuria in humans identifies threonine 137 as an important determinant of sodium-phosphate cotransport in NaPi-IIcThe emerging role of the fibroblast growth factor-23-klotho axis in renal regulation of phosphate homeostasisEndocrine functions of bone in mineral metabolism regulation.The Na+-Pi cotransporter PiT-2 (SLC20A2) is expressed in the apical membrane of rat renal proximal tubules and regulated by dietary PiAutosomal dominant hypophosphatemic rickets in an 85 year old woman: characterization of her disease from infancy through adulthood.Kidney and phosphate metabolism.Renal phosphate handling in human--what can we learn from hereditary hypophosphataemias?Phosphate homeostasis and the renal-gastrointestinal axis.The phosphate regulating hormone fibroblast growth factor-23.Hypophosphatemia and growth.Genetic diseases of renal phosphate handling.X-linked hypophosphatemia and growth.Effects of phospho- and calciotropic hormones on electrolyte transport in the proximal tubule.Renal phosphaturia during metabolic acidosis revisited: molecular mechanisms for decreased renal phosphate reabsorption.Npt2a and Npt2c in mice play distinct and synergistic roles in inorganic phosphate metabolism and skeletal development.Parathyroid hormone (PTH) decreases sodium-phosphate cotransporter type IIa (NpT2a) mRNA stability.The phosphate transporter NaPi-IIa determines the rapid renal adaptation to dietary phosphate intake in mouse irrespective of persistently high FGF23 levels.Hypophosphatemia in vitamin D receptor null mice: effect of rescue diet on the developmental changes in renal Na+ -dependent phosphate cotransporters.Internalization of renal type IIc Na-Pi cotransporter in response to a high-phosphate diet.Phex mutation causes the reduction of npt2b mRNA in teeth.
P2860
Q24299058-C169ACC3-8EF9-4316-869F-E47DFD5EE065Q24540520-E038F4FC-8BF6-4D7C-A734-F97838366C95Q33307695-E5B6872F-CD31-4B13-B447-50B0ADF72E29Q33634310-A5D6F835-57A7-4BFD-8F89-86F24EF23FCDQ33892284-DBAE8712-203F-4D66-9780-61F73D343A3AQ34030128-B064C339-BCF2-4DA0-8C87-405CC61CE71FQ34442093-F514B1AD-F06E-4D91-8EE6-688DC5EF8AFBQ35538411-3BAB3820-D4CC-4207-9E02-DBDF95B3E628Q35911345-7B6CE13B-5DC6-47A1-84AF-2CD9B93EED4CQ36216970-76DF4413-6D66-4F43-9848-7E0ED793C266Q36770978-735DB6F9-57E4-484E-9DEB-4D5D2EBDF7B1Q36842429-36016512-73F8-47EA-8BE4-92EFB65AA678Q36844496-21E58B1B-DAB1-4A57-B804-E68214016A00Q36860289-A066788F-45F8-4A08-99C7-41115522E2CEQ36982323-7A48DF55-E95E-4D5B-9C78-578CEDD7C24EQ37162336-30ABEFC1-29E5-49A2-A7A1-7461469A790FQ37406152-F9BBFBDC-B9A4-4ECB-9025-45547958E9FAQ37488973-065565B2-7049-44D2-A8D6-10C28FCE6461Q37735893-3C8A49AB-330F-4FDF-937B-498CF1F5F6AAQ37763810-C2022C76-899C-46D6-BB30-738493FC4F1DQ37771349-5D60E6D9-3CCC-432D-99AF-661B4B3FB8ADQ38062345-39B1900B-A423-485C-8034-050FDEFE2AF8Q38244118-7DD8F799-CC26-4989-9EF7-E62164FAA049Q39107200-07AF1712-2E94-4238-B334-B08A34F48C45Q42370104-9E9BC64D-A3AC-4047-A8CE-5C317F028C75Q44010275-BAED80AA-AAD2-4513-A9D4-65B66FBD2289Q46274827-38D95F17-9B12-4152-A6DA-280EC577768AQ48532920-59C2F6C7-2723-4F49-BDFD-839CCC562070Q50959402-69040B04-C462-4CFE-98D3-5D56CBF04715Q51896177-7FAD5C55-5477-454F-B420-2E8AC3A36024Q52561362-AB53568D-D057-45C4-BE90-F65F07985204Q54560426-94B3C2B1-AAD4-4598-972D-434D713510DD
P2860
Differential effects of Npt2a gene ablation and X-linked Hyp mutation on renal expression of Npt2c.
description
2003 nî lūn-bûn
@nan
2003年の論文
@ja
2003年学术文章
@wuu
2003年学术文章
@zh
2003年学术文章
@zh-cn
2003年学术文章
@zh-hans
2003年学术文章
@zh-my
2003年学术文章
@zh-sg
2003年學術文章
@yue
2003年學術文章
@zh-hant
name
Differential effects of Npt2a ...... on renal expression of Npt2c.
@en
Differential effects of Npt2a ...... on renal expression of Npt2c.
@nl
type
label
Differential effects of Npt2a ...... on renal expression of Npt2c.
@en
Differential effects of Npt2a ...... on renal expression of Npt2c.
@nl
prefLabel
Differential effects of Npt2a ...... on renal expression of Npt2c.
@en
Differential effects of Npt2a ...... on renal expression of Npt2c.
@nl
P2093
P2860
P1476
Differential effects of Npt2a ...... on renal expression of Npt2c.
@en
P2093
Claude Gauthier
Harriet S Tenenhouse
Hiroko Segawa
Josée Martel
Ken-ichi Miyamoto
P2860
P304
P356
10.1152/AJPRENAL.00252.2003
P577
2003-09-02T00:00:00Z