Maternal loss of 24-hydroxylase causes increased intestinal calcium absorption and hypercalcemia during pregnancy but reduced skeletal resorption during lactation in mice.

ABSTRACT

Inactivation of 24-hydroxylase (CYP24A1) causes mild hypercalcemia in humans that becomes severe and life-threatening during pregnancy through unclear mechanisms. We studied Cyp24a1 null mice during pregnancy, lactation, and post-weaning. We hypothesized that Cyp24a1 nulls have a much greater increase in calcitriol during pregnancy and lactation, leading to markedly increased intestinal calcium absorption and reduced lactational bone loss. WT and Cyp24a1 null sisters were mated to Cyp24a1+/- males. Timepoints included baseline (BL), late pregnancy (LP), mid-lactation (ML), late lactation (LL), and weekly x4 weeks of post-weaning recovery (R1-4). Assessments included intestinal calcium absorption (IntCaAbs) by gavage of 45Ca, bone mineral content (BMC) by DXA, microCT of femurs, 3-point bending tests of tibias, serum hormones, serum and urine minerals, milk analysis, and intestinal gene expression. At LP, whole body BMC increased equally by ~12% in null and WT. Calcitriol was 2.5-fold higher in nulls vs WT, accompanied by 3-fold increased IntCaAbs, hypercalcemia, hypercalciuria, and 6.5-fold higher FGF23. PTH was suppressed in both. Twenty percent of null dams died during delivery but their serum calcium at LP did not differ from Cyp24a1 nulls that survived. At ML, calcitriol, IntCaAbs, and FGF23 declined in both genotypes but remained higher than BL values in Cyp24a1 nulls. By LL, nulls were still hypercalcemic vs WT, and had lost less mean whole body BMC (11% vs. 21%, P<.02), but by micro-CT there were no differences from WT in cortical or trabecular bone mass. Lactational losses in BMC, cortical thickness, and trabecular number were restored by R4 in both genotypes. In summary, ablation of Cyp24a1 increased IntCaAbs and caused hypercalcemia during pregnancy and lactation, late gestational mortality in some nulls, and reduced lactational BMC loss. Treating women with gestational hypercalcemia from CYP24A1 mutations should focus on reducing calcitriol or IntCaAbs, since increased bone resorption is not the cause.

24-hydroxylase breaks down calcitriol, the hormonal form of vitamin D. Genetic deficiency of 24-hydroxylase causes mildly increased blood calcium (hypercalcemia) in adult humans, which can become life-threateningly high during pregnancy. We used a genetically engineered mouse model to determine the cause of this severe hypercalcemia. Calcitriol increased 10-fold during pregnancy in 24-hydroxylase deficient mice versus 4-fold in normal pregnant mice. High calcitriol in turn caused a marked increase in intestinal calcium absorption, which explained the hypercalcemia. Some 24-hydroxylase deficient mice died in late pregnancy. Our findings indicate that affected pregnant women need treatments that specifically reduce intestinal calcium absorption.