Intestinal malabsorption of 45calcium in young Gy mice, a second model for X-linked hypophosphatemia

Effects of altered diet on serum levels of 1,25-dihydroxyvitamin D and parathyroid hormone in X-linked hypophosphatemic (Hyp and Gy) mice

X-linked hypophosphatemia is a metabolic bone disease occurring in both humans and mice. In mice, two different mutations (Hyp and Gy), occurring at separate but closely linked loci, have been proposed as models for this disease. Varying reports of the Vitamin D status of these two mutants has led us to reexamine the influence of diet on circulating calcitrophic hormones and mineral metabolism in both mutants. Hyp and Gy mice were raised on the B6C3H background, and both normal females and heterozygous mutant females were studied at 10 weeks of age. Animals were fed one of three diets at random: high (1.5% Ca and 1.0% P); medium (0.6% Ca and 0.6% P); or low (0.0% Ca and 0.6% P). After 3 days, serum and urine samples were collected. In comparison to mutant mice fed the high diet, both Hyp and Gy mice fed the low diet had decreased serum calcium levels, and further elevations in both serum alkaline phosphatase and serum parathyroid hormone (PTH). Serum 1,25-dihydroxyvitamin D levels were elevated by both the medium and low diets in all groups of mice over values obtained with the high diet. Mutant mice were significantly higher in serum PTH on all diets compared to normal mice fed the same diet. Mutant mice were not elevated in serum 1,25-dihydroxyvitamin D over normal mice when fed the high diet. However, both Hyp and Gy mice fed the medium and low diets were elevated in serum 1,25-dihydroxyvitamin D over normal mice. Serum PTH levels were correlated to serum 1,25-dihydroxyvitamin D levels with Hyp and Gy mice lying on the same line (r = 0.86; p < 0.0001). In summary, when Hyp and Gy mice are studied on the same genetic background and fed the same diet, similar responses are seen in PTH levels and 1,25-dihydroxyvitamin D levels. Both mutants should be useful in elucidating the pathophysiology of this poorly understood human disease.

Femoral abnormalities and vitamin D metabolism in X-linked hypophosphatemic (Hyp and Gy) mice

X-linked hypophosphatemia is a genetic bone disease in humans and mice. Two closely linked mutations in mice, Hyp and Gy, cause low plasma phosphate and a rachitic and osteomalacic bone disease. Because of the controversy as to whether Gy is a good model for X-linked hypophosphatemia, the phenotypic severity of these two mutations was compared in both sexes and on two genetic backgrounds. The depression in plasma levels of phosphate was similar in all 10-week-old mutant mice. Male Hyp mice and heterozygous female Hyp mice were affected with similar severity in terms of reduced tail growth, shortened femora, reduced femoral mineral content, and abnormal mineral composition of the femoral matrix. In contrast, male Gy mice did not survive on the C57BL/6J background and were more severely affected than female Gy mice on the B6C3H background. The hybrid B6C3H background ameliorated the bone disease compared with the inbred C57BL/6J background for both mutant strains. There was no evidence of change in the plasma levels of 1,25-dihydroxyvitamin D, duodenal level of vitamin D-dependent calcium-binding protein, or urinary level of calcium in these adult mutant mice. In summary, Gy mice have a sexual dimorphism not present in Hyp mice. These two genes may indicate the presence of multiple gene loci in the human disease, with multiple proteins involved in the pathophysiology of the bone disease.

Phosphate transport in osteoblasts from normal and X-linked hypophosphatemic mice

Human hypophophatemic vitamin D-resistant rickets (X-linked hypophosphatemia-XLH) is characterized by hypophosphatemia, a decreased tubular reabsorption of phosphate (P(i)) and defective skeleton mineralization. Utilizing a mouse model (Hyp) of XLH, which demonstrates biological abnormalities and skeletal defects of XLH, we analyzed sodium-dependent phosphate transport in isolated osteoblasts derived from the calvaria of normophosphatemic and hypophosphatemic mice. Initial rates of phosphate uptake by normal and Hyp osteoblasts showed similar slopes. Osteoblasts from both normal and Hyp mice exhibited saturable, sodium-dependent phosphate transport with apparent Vmax and Km values not significantly different (normal mice, Vmax = 24.30 +/- 3.45 nmol/mg prot. 10 min, Km = 349.49 +/- 95.20 mumol/liter; Hyp mice, Vmax = 23.03 +/- 3.41 nmol/mg prot. 10 min, Km = 453.64 +/- 106.93 mumol/liter, n = 24). No differences were found in the ability of normal and Hyp osteoblasts to respond to P(i) transport after 5 hours of P(i) deprivation. Both cell types exhibited a similar increase in cAMP in response to PTH. The accumulated results demonstrate that P(i) uptake and transport in normal and Hyp mouse osteoblasts is a sodium-dependent saturable process. As osteoblast P(i) uptake and transport is apparently normal in the Hyp mouse model of XLH, the "osteoblastic failure" described for the Hyp mouse should be attributed to other mechanism(s).