Differential effects of oral doxercalciferol (Hectorol) or paricalcitol (Zemplar) in the Cyp27b1-null mouse model of uremia.

BACKGROUND/AIMS: Kidney disease patients experience declining calcitriol levels and develop secondary hyperparathyroidism (SHPT). Animal models of uremia based on 5/6 nephrectomy (NTX) do not consistently reproduce this calcitriol deficiency. We developed an animal model, the NTX Cyp27b1-null mouse, which completely lacks endogenous calcitriol, and examined the suitability of this model for evaluation of treatment with vitamin D analogs in uremia. METHODS: NTX was performed at 2 months of age. One week post-NTX, animals were treated for 4 weeks with vehicle; doxercalciferol at 30, 100 or 300 pg/g body weight (b.w.); or paricalcitol at 100, 300 or 1,000 pg/g b.w. by gavage 3 times per week. RESULTS: Serum blood urea nitrogen and creatinine were elevated. Vehicle-treated NTX null mice had hypocalcemia and SHPT. Doxercalciferol at 100 or 300 pg/g b.w. normalized serum calcium and parathyroid hormone (PTH) levels. Paricalcitol at 300 or 1,000 pg/g normalized serum calcium, but PTH levels remained elevated. Osteomalacia was corrected by 100 pg/g b.w. of doxercalciferol or 1,000 pg/g b.w. of paricalcitol. The highest dose of doxercalciferol, but not of paricalcitol, significantly reduced osteitis fibrosa. CONCLUSION: Our results reveal the differential efficacy of doxercalciferol and paricalcitol in this novel animal model incorporating both calcitriol deficiency and renal insufficiency.

Hepatic activation and inactivation of clinically-relevant vitamin D analogs and prodrugs.

Like most pharmaceutical agents, vitamin D analogs are subject to hepatic metabolism by a variety of cytochrome P450 (CYP)-based systems. Metabolism can involve activation as well as inactivation of the vitamin D analog and one of the more successful families includes the 1alpha-hydroxyvitamin D prodrugs (1alpha-OH-D2, 1alpha-OH-D3, 1alpha-OH-D4, 1alpha-OH-D5), that all require a step of activation. Some of these prodrugs are in use or clinical trial because they have a therapeutic advantage over calcitriol. However, the nature of the activation of these molecules is poorly understood, particularly with regard to the CYP isoform involved. Various transfected CYPs and hepatic cell lines combined with tandem LC-MS analysis were used to investigate the metabolism of a spectrum of vitamin D analogs, including 1alpha-OH-Ds and the topical analog, calcipotriol. In the case of the 1alpha-OH-Ds, evidence was found of multiple sites of side-chain hydroxylation consistent with the generation of more than one active form. The potential involvement of CYP27A and other putative 25-hydroxylases in 1alpha-OH-D activation was also shown, as well as the potential for CYP24 activation and inactivation. In the case of calcipotriol, the respective roles of non-vitamin D-related CYPs and CYP24 in the catabolism of this anti-psoriatic drug were dissected out using cell lines with or without CYP24 expression, allowing us to demonstrate the potential contribution of CYP24 to "vitamin D resistance". The implications of hepatic metabolism in the context of other facets thought to play a role in the mechanism of action of anticancer and antiproliferative vitamin D analogs are discussed.

Evidence for the activation of 1alpha-hydroxyvitamin D2 by 25-hydroxyvitamin D-24-hydroxylase: delineation of pathways involving 1alpha,24-dihydroxyvitamin D2 and 1alpha,25-dihydroxyvitamin D2.

While current dogma argues that vitamin D prodrugs require side-chain activation by liver enzymes, recent data suggest that hydroxylation may also occur extrahepatically. We used keratinocytes and recombinant human enzyme to test if the 25-hydroxyvitamin D-24-hydroxylase (CYP24A1) is capable of target cell activation and inactivation of a model prodrug, 1alpha-hydroxyvitamin D2 (1alpha(OH)D2) in vitro. Mammalian cells stably transfected with CYP24A1 (V79-CYP24A1) converted 1alpha(OH)D2 to a series of metabolites similar to those observed in murine keratinocytes and the human cell line HPK1A-ras, confirming the central role of CYP24A1 in metabolism. Products of 1alpha(OH)D2 included the active metabolites 1alpha,24-dihydroxyvitamin D2 (1alpha,24(OH)2D2) and 1alpha,25-dihydroxyvitamin D2 (1alpha,25(OH)2D2); the formation of both indicating the existence of distinct activation pathways. A novel water-soluble metabolite, identified as 26-carboxy-1alpha,24(OH)2D2, was the presumed terminal degradation product of 1alpha(OH)D2 synthesized by CYP24A1 via successive 24-hydroxylation, 26-hydroxylation and further oxidation at C-26. This acid was absent in keratinocytes from Cyp24a1 null mice. Slower clearance rates of 1alpha(OH)D2 and 1alpha,24(OH)2D2 relative to 1alpha,25(OH)2D2 and 1alpha,25(OH)2D3 were noted, arguing for a role of 24-hydroxylated metabolites in the altered biological activity profile of 1alpha(OH)D2. Our findings suggest that CYP24A1 can activate and inactivate vitamin D prodrugs in skin and other target cells in vitro, offering the potential for treatment of hyperproliferative disorders such as psoriasis by topical administration of these prodrugs.

The vitamin D prodrugs 1alpha(OH)D2, 1alpha(OH)D3 and BCI-210 suppress PTH secretion by bovine parathyroid cells.

BACKGROUND: Active vitamin D compounds are widely used in the treatment of secondary hyperparathyroidism associated with renal failure. These compounds reduce PTH secretion through vitamin D receptor (VDR)-dependent repression of PTH gene transcription. In previous studies, 1alpha(OH)D3, a vitamin D prodrug, inhibited PTH secretion in cultured bovine parathyroid cells, but it was unclear whether 1alpha(OH)D3 itself or an active metabolite produced this inhibition. METHODS: We determined the effectiveness of the vitamin D prodrugs 1alpha(OH)D3, 1alpha(OH)D2 and 1alpha(OH)-24(R)-methyl-25-ene-D2 (BCI-210) at inhibiting PTH secretion in bovine parathyroid cell cultures, and examined the metabolism of [3H]1alpha(OH)D2 in these cells. RESULTS: All three prodrugs suppressed PTH secretion with approximately 10% of the activity of 1,25(OH)2D3; much higher activity than expected based on the VDR affinities of these prodrugs (0.25% of 1,25(OH)2D3). Parathyroid cells activated [3H]1alpha(OH)D2 to both 1,25(OH)2D2 and 1,24(OH)2D2. 1,24(OH)2D2 was detectable at 4 h, increased to a maximum at 8 h, and then decreased. In contrast, 1,25(OH)2D2 levels increased linearly with time, suggesting the presence of constitutively active vitamin D-25-hydroxylase not previously reported in parathyroid cells. The cytochrome P-450 inhibitor ketoconazole (50 microM) reduced 1alpha(OH)D2 metabolism to below detectable levels, but did not significantly affect suppression of PTH by 1alpha(OH)D2. CONCLUSIONS: The vitamin D prodrugs 1alpha(OH)D3, 1alpha(OH)D2 and BCI-210 suppressed PTH production by cultured parathyroid cells. The ability of 1alpha(OH)D2 to reduce PTH despite inhibition of its metabolism suggests a direct action of this 'prodrug' on the parathyroid gland, but the mechanism underlying this activity is not yet known.

1,24(S)-dihydroxyvitamin D2, an endogenous vitamin D2 metabolite, inhibits growth of breast cancer cells and tumors.

BACKGROUND: 1,24-Dihydroxyvitamin D2 (1,24(OH)2D2) is a naturally occurring metabolite of vitamin D2 with low calcemic activity and potent antiproliferative activity. We evaluated the activity of 1,24(OH)2D2 in breast cancer models. MATERIALS AND METHODS: The antiproliferative activity of 1,24(OH)2D2 was quantitated against human and murine breast cancer cell lines. The antitumor activity of 1,24(OH)2D2 was quantitated using MCF-7 xenografts in nude mice. RESULTS: 1,24(OH)2D2 inhibited growth of vitamin D receptor (VDR)-positive, but not VDR-negative, breast cancer cells. 1,24(OH)2D2 (10 microg/kg or 50 microg/kg) reduced MCF-7 xenograft growth by 50% after five weeks. Tumor morphology in treated animals was consistent with replacement of epithelial cells by stromal tissue. Mice treated with 1,24(OH)2D2 showed no loss of body weight, hypercalcemia or kidney calcification. CONCLUSION: 1,24(OH)2D2 inhibits growth of breast cancer cells via VDR-dependent mechanisms; its complete lack of toxicity and significant antitumor activity supports further development for chemotherapeutic applications.

Tissue distribution and activity studies of 1,24-dihydroxyvitamin D2, a metabolite of vitamin D2 with low calcemic activity in vivo.

The active vitamin D compound 1alpha,24(S)-dihydroxyvitamin D(2) (1,24(OH)(2)D(2)) is under development as a therapy for disorders including cancer and secondary hyperparathyroidism. 1,24(OH)(2)D(2) is a potent inhibitor of cell proliferation in vitro and, relative to calcitriol (1,25(OH)(2)D(3)), has reduced calcemic activity in vivo. To examine the mechanisms underlying this reduced calcemic activity, we studied the tissue distribution in rats of radiolabeled 1,24(OH)(2)D(2) or 1,25(OH)(2)D(3) over 24h. Serum levels of 1,24(OH)(2)D(2) were lower than those of 1,25(OH)(2)D(3) at all time points; however, tissue levels of radiolabeled compounds followed different patterns. In duodenum and kidney, 1,24(OH)(2)D(2) and 1,25(OH)(2)D(3) rose to similar levels at early time points; 1,24(OH)(2)D(2) levels then declined more rapidly. In bone marrow, 1,24(OH)(2)D(2) and 1,25(OH)(2)D(3) were present at similar levels at all time points. In liver, 1,24(OH)(2)D(2) levels were two-fold higher than 1,25(OH)(2)D(3) at 1h post-injection, declining to similar levels by 8h. In vitamin D-deficient rats, doses of 1,24(OH)(2)D(2) 30-fold higher than 1,25(OH)(2)D(3) were required to produce equal stimulation of intestinal calcium absorption. In the same deficient animals, 1,24(OH)(2)D(2) and 1,25(OH)(2)D(3) were nearly equipotent at stimulating bone calcium mobilization. In cultured bone cells, 1,24(OH)(2)D(2) and 1,25(OH)(2)D(3) were equipotent at stimulating osteoclast formation and bone resorption. In summary, the reduced calcemic activity of 1,24(OH)(2)D(2) may result from altered pharmacokinetics relative to 1,25(OH)(2)D(3), resulting in relatively rapid decreases in 1,24(OH)(2)D(2) levels and activity in target organs such as intestine. Further studies will be necessary to confirm these findings and to confirm the clinical utility of 1,24(OH)(2)D(2).

Insights into Vitamin D metabolism using cyp24 over-expression and knockout systems in conjunction with liquid chromatography/mass spectrometry (LC/MS).

The development of novel gene expression systems for cytochrome P450s (CYPs) together with a revolution in analytical mass spectrometry with the emergence of liquid chromatography/mass spectrometry (LC/MS) has opened the door to answering some long-standing questions in Vitamin D metabolism. Our studies focused on: (1) elucidating the role of CYP24 in 25-OH-D3 and 1alpha,25-(OH)2D3 metabolism; (2) exploring how DBP influences this process; (3) measuring 25-OH-D3 metabolism in CYP24-knockout (CYP24-XO) cells and; (4) comparing 1alpha-OH-D2 metabolism in the CYP24-XO mouse in vivo and in vitro. Methodology employed CYP24 over-expression and knockout systems in conjunction with state-of-the-art analytical LC/MS, diode array, and radioisotopic detection methods. We found that CYP24 metabolizes 25-OH-D3 and 1alpha,25-(OH)2D3 at similar rates in vitro, but that for 25-OH-D3 but not 1alpha,25-(OH)2D3, this rate is strongly influenced by the concentration of DBP. Unlike their wild type littermates, the administration of 25-OH-D3 to CYP24-XO mice results in no measurable 24,25-(OH)2D3 production. When neonatal murine keratinocytes are prepared from wild type and CYP24-XO mice there was no measurable production of 24,25-(OH)2D3 or 1alpha,24,25-(OH)2D3 in CYP24-XO mice. Similar experiments using the same wild type and CYP24-XO animals and cells and [3H] 1alpha-OH-D2 resulted in the apparent paradox that the Vitamin D prodrug was 25-hydroxylated in vivo but 24-hydroxylated in vitro.

Pharmacokinetics of doxercalciferol, a new vitamin D analogue that lowers parathyroid hormone.

BACKGROUND: This is the first detailed pharmacokinetic report published on the administration of doxercalciferol [1alpha(OH)D(2)] recently introduced to treat secondary hyperparathyroidism. METHODS: 1alpha(OH)D(2) was administered in a range of single and multiple doses to volunteers with and without normal renal and/or hepatic function. Subsequent serial blood samples were assayed by HPLC/radioimmunoassay for the metabolite 1,25-dihydroxyvitamin D(2) [1,25(OH)(2)D(2)], the major active species. RESULTS: Bioavailability of 1,25(OH)(2)D(2) from a single 5 micro g 1alpha(OH)D(2) oral-capsule dose was estimated to be normally approximately 42% of that from a 5 micro g intravenous injection. Steady-state serum concentrations of 1,25(OH)(2)D(2) were attainable within 8 day, and fluctuated approximately 2.5-fold from peak to trough when oral 1alpha(OH)D(2) doses were taken every second day, and the terminal half-life was 34+/-14 h. Mean steady-state serum concentrations rose less than proportionally (from 20 to 45 pg/ml) on increasing oral 1alpha(OH)D(2) doses from 5 to 15 micro g every 48 h. Renal patients showed 39+/-37% increase in serum 1,25(OH)(2)D(2) concentration during 3-4 h haemodialysis sessions, but no other difference in steady-state pharmacokinetics was found between these or hepatically impaired patients and normal subjects. CONCLUSIONS: Given the sensitivity limits of current assays, the pharmacokinetics of this and other vitamin-D compounds is best elucidated from steady-state studies. The pharmacokinetics of 1,25(OH)(2)D(2) from 1alpha(OH)D(2) doses appears to be similar to that of 1,25(OH)(2)D(3) from 1alpha(OH)D(3) doses, albeit D(3) data have to date largely derived from single-dose studies. Deviation of 1,25(OH)(2)D(2) pharmacokinetics from linearity appears to be marginal enough to be clinically manageable with adequate precaution.

Use of vitamin D(4) analogs to investigate differences in hepatic and target cell metabolism of vitamins D(2) and D(3).

In this study, we used molecules with either of the structural differences in the side chains of vitamin D(2) and vitamin D(3) to investigate which feature is responsible for the significant differences in their respective metabolism, pharmacokinetics and toxicity. We used two cell model systems-HepG2 and HPK1A-ras-to study hepatic and target cell metabolism, respectively. Studies with HepG2 revealed that the pattern of 24- and 26-hydroxylation of the side chain reported for 1alpha-hydroxyvitamin D(2) (1alpha-OH-D(2)) but not for 1alpha-OH-D(3) is also observed in both 1alpha-OH-D(4) and Delta(22)-1alpha-OH-D(3) metabolism. This suggests that the structural feature responsible for targeting the enzyme to the C24 or C26 site could be either the C24 methyl group or the 22-23 double bond. In HPK1A-ras cells, the pattern of metabolism observed for the 24-methylated derivative, 1alpha,25-(OH)(2)D(4), was the same pattern of multiple hydroxylations at C24, C26 and C28 seen for vitamin D(2) compounds without evidence of side chain cleavage observed for vitamin D(3) derivatives, suggesting that the C24 methyl group plays a major role in this difference in target cell metabolism of D(2) and D(3) compounds. Novel vitamin D(4) compounds were tested and found to be active in a variety of in vitro biological assays. We conclude that vitamin D(4) analogs and their metabolites offer valuable insights into vitamin D analog design, metabolic enzymes and maybe useful clinically.