Martha H. Meyer

Picric acid methods greatly overestimate serum creatinine in mice: More accurate results with high-performance liquid chromatography☆

The creatinine levels of blood and urine from humans, rats, and mice were measured by high-performance liquid chromatography. These were compared to the alkaline picrate analysis of creatinine performed by standard colorimetric, kinetic, and AutoAnalyzer techniques. For human serum and urine the values obtained using the HPLC technique gave good agreement with four out of five alkaline picrate techniques. For black or white mice, the serum creatinine concentration was 8.7 +/- 0.4 microM by HPLC but 44.9 +/- 1.9 microM by the lowest alkaline picrate method. Mouse urine creatinine concentrations were 3.24 +/- 0.19 mM by HPLC and 4.59 +/- 0.39 mM by the nearest alkaline picrate method. Rat serum creatinine concentrations analyzed by HPLC were about half the values obtained by AutoAnalyzer. Mouse and rat samples seemed to have substances which gave nonspecific color and thus interfered with the analysis of creatinine by the alkaline picrate methods. While the alkaline picrate analysis of creatinine was adequate for human samples, it was necessary to use HPLC to accurately measure rodent creatinine. The fractional excretion of creatinine was determined by measuring creatinine in mouse urine and plasma by both the kinetic and HPLC methods and comparing these values to urine and plasma inulin. Using the kinetic method, creatinine was cleared at 43 +/- 3% of the rate of inulin. Using the HPLC method, creatinine was cleared at 170 +/- 11% of the rate of inulin.

Osteomalacia and altered magnesium metabolism in the X-linked hypophosphatemic mouse.

SummaryA new genetic mutant in mice,Hyp, has been proposed as a model for the human disease X-linked hypophosphatemia (the most common form of vitamin D-resistant rickets). The gene is X-linked, dominant, and produces reduced renal tubular reabsorption of phosphate, hypophosphatemia, and dwarfism. Our goal was to evaluate the skeletal changes histologically and to measure chemically the prominant blood and bone minerals to judge the suitability of this mutant as a model for the human disease. Thirteen-week-old hemizygousHyp male mice were compared with their normal littermate controls. TheHyp mice were hypocalcemic, hypophosphatemic, hypermagnesemic, and had elevated plasma alkaline phosphatase. The femur ash weighed less than half the normal ash weight but had a normal Ca:P ratio. The ash composition was high in %Na and K but low in %Mg. The mandibular incisor ash was also low in %Mg. Histologically the femur showed wide osteoid borders and wide epiphyseal plate. Microradiography revealed reduced bone density and enlarged osteocyte lacunae. Skeletal muscle samples, although smaller in theHyp mice, showed no striking alternations in inorganic or total phosphate content, dry weight (as % wet weight), or extracellular fluid space. TheHyp gene in mice seems to produce a condition similar to that of X-linked hypophosphatemia in humans.

Response of tissue phosphate content to acute dietary phosphate deprivation in the X-linked hypophosphatemic mouse

SummaryIn order to evaluate a possible role for tissue phosphate or phosphorylated compounds in mediating the increase in plasma 1,25(OH)2D3 levels during dietary phosphate deprivation, renal cortical phosphate content has been measured in both normal and X-linked hypophosphatemic mice on a normal diet and also after acute dietary phosphate deprivation. We find that the metabolism of inorganic phosphate and phosphorylated organic compounds in the renal cortex ofHyp mice is not altered in response to their very low levels of serum phosphate. Skeletal muscle does not lose inorganic phosphate and/or phosphorylated metabolites to compensate for drastic loses of serum phosphate during acute dietary deprivation in either normal orHyp mice. Furthermore, the chronic low level of serum phosphate and altered hormonal regulation inHyp mice do not produce alterations in mineral composition of the bone with the possible exception that the stoichiometry of the apatite might be slightly different.

Reduced absorption of 45calcium from isolated duodenal segments in vivo in juvenile but not adult X-linked hypophosphatemic mice.

SummaryIn juvenile X-linked hypophosphatemic (Hyp) mice, whole body calcium balances are significantly lower than in genetically normal mice. This is associated with low duodenal vitamin D-dependent calcium-binding protein and a failure of skeletal mineralization. To seek more specific evidence of an intestinal defect in these mice, absorption of45Ca was measured in isolated duodenal segmentsin vivo in mice from 2–13 weeks of age. The duodenum was isolated by sutures and45Ca was injected into the lumen in 150 mM NaCl and 2 mM CaCl2 at pH=7.2. Absorption was measured by the amount of isotope remaining in the lumen and by the plasma isotope level. HemizygousHyp male and heterozygousHyp female mice absorbed significantly less45Ca at 4 and 7 weeks of age than genetically normal mice whileHyp mice at 2, 10, and 13 weeks of age were not significantly affected. At 4 and 7 weeks of age, theHyp mice also had significantly reduced plasma radioactivity midway through the collection period as well as at the end of the period. To explore a possible mechanism for this malabsorption, 1,25(OH)2-vitamin D receptors were measured in cytosol prepared from 4-week-old normal andHyp duodenum. There were non-significant differences between the normal andHyp mice in both binding affinity, Kd, and the number of receptors, nmax. In conclusion, juvenileHyp mice at 4 and 7 weeks of ages malabsorbed calcium from their duodenum.Hyp mice younger than this period were not affected nor were adultHyp mice. This delay in the development of calcium absorption was not caused by a delay in the appearance of intestinal receptors for 1,25(OH)2D.

Malabsorption of phosphate by the intestines of young X-linked hypophosphatemic mice

SummaryX-linked hypophosphatemic (Hyp) mice are a model for human X-linked (familial) hypophosphatemia (vitamin D-resistant rickets). In several studies, Hyp mice have been shown to exhibit either normal intestinal phosphate absorption or malabsorption of phosphate. These apparently conflicting reports led us to further investigate intestinal phosphate absorption. Isolated intestinal segmentsin vivo were used in C57BL/6J normal and Hyp mice, both male and female.33P was placed in the segment in 2 mM Na2HPO4+150 mM NaCl, pH 7.2. Mice at 4, 7, and 12 weeks of age were used. No significant differences in phosphate absorption were found between the sexes. At 4 weeks of age, Hyp mice showed significant malabsorption of phosphate, with the jejunum being the most severely affected. Malabsorption was judged by significantly more33P remaining in the lumen, less in the intestinal tissue, and less in the plasma. At 7 weeks of age, these same trends were seen but at a nonsignificant level. By the 12th week of life, the absorption of33P was similar in Hyp and normal mice. Thus, phosphate malabsorption in Hyp mice is an age-related phenomena. These changes parallel the malabsorption of calcium in young Hyp mice and reflect the lowered plasma 1,25-dihydroxyvitamin D (1,25(OH)2D) levels of young Hyp mice.

Metabolites of vitamin D in normal and X-linked hypophosphatemic mice

SummaryHyp mice are a model for human X-linked hypophosphatemia (vitamin D-resistant rickets.) To determine whether an abnormality of vitamin D metabolism exists in this disease, the profiles of the metabolites of vitamin D were determined in normal andHyp mouse plasma.Hyp and normal mice were fed a vitamin D-deficient diet and received 1,23H-vitamin D3 at 16 Ci/mmol by stomach tube at 5 ng/g body weight (0.21 µCi/g b.w.) on alternate days for 14 days. The dose of vitamin D given maintained near normal plasma 25-OH-vitamin D. Thus the mice were in a vitamin D-replete state with all metabolite pools labeled with3H. Plasma was collected from 4 normal and 4Hyp mice. The plasma was extracted, and the extracts were chromatographed separately for each mouse on an LH-20 column. Each major peak of radioactivity was rechromatographed using high performance liquid chromatography on a Zorbax-Sil column using solvent systems known to resolve several vitamin D metabolites. Twenty-one radioactive peaks were identified. The disintegrations per minute of3H in each peak were quantified and converted to plasma concentration using the known specific activity of the administered vitamin D. The 25-OH-vitamin D accounted for 55% of the circulating radioactivity, and 24,25-(OH)2-vitamin D accounted for 22%. The plasma levels of 24,25-(OH)2-vitamin D were similar to levels previously reported by us using protein binding assays. No peaks of radioactivity were missing in the plasma extracts of theHyp mice. Also there was no evidence that plasma 24,25-(OH)2-vitamin D was elevated in theHyp mice.

Phosphate mobilization from striated muscle following parathyroid hormone administration to thyroparathyroidectomized rats.

Parathyroid hormone administration to thyroparathyroidectomized rats resulted in a significant reduction in inorganic phosphate content of a variety of striated muscles. Most other organs were unaffected. Much of the extra urinary phosphate present after parathyroid hormone stimulation may be released from the muscles.

Increased liver calcium after calcium or milk gavage in rats.

For 1 or 2 h following a gavage of milk or 300 mM CaCl2 (2 ml/100 g b.wt), rats had an increased liver calcium content when compared to rats receiving a deionized water gavage.