Metabolism of (3alpha-3H)25-hydroxyvitamin D2 in kidneys isolated from normal and vitamin D2-intoxicated rats

With the availability of A-ring labelled 25OHD2, [3α-3H] 25OHD2, we have performed the present study to examine the metabolism of 25OHD2 using physiological substrate concentrations in perfused kidneys isolated from both normal and vitamin D2-intoxi-cated rats. Our results indicate that [3α-3H] 25OH...

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Published in:Journal of Nutritional Science and Vitaminology 2000, Vol.46(5), pp.222-229
Main Authors: Rao, D.S. (Brown Univ., Rhode Island (USA)), Ray, R, Holick, M.F, Horst, R.L, Uskokovic, M.R, Reddy, G.S
Format: Article
Language:English
Subjects:
25-Hydroxyvitamin D 2 - analogs & derivatives
25-Hydroxyvitamin D 2 - metabolism
25OHD2
Animals
Biological and medical sciences
Chromatography, High Pressure Liquid
Ergocalciferols - metabolism
Ergocalciferols - toxicity
hydroxylation
kidney
Kidney - metabolism
KIDNEYS
Male
Medical sciences
Metabolic diseases
METABOLISM
Other nutritional diseases (malnutrition, nutritional and vitamin deficiencies...)
Perfusion
polar water-soluble metabolite(s)
RATS
Rats, Sprague-Dawley
Time Factors
Tritium
VITAMIN D
vitamin D2-intoxicated rats
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Summary:With the availability of A-ring labelled 25OHD2, [3α-3H] 25OHD2, we have performed the present study to examine the metabolism of 25OHD2 using physiological substrate concentrations in perfused kidneys isolated from both normal and vitamin D2-intoxi-cated rats. Our results indicate that [3α-3H] 25OHD2 is metabolized into both 24(S), 25, 28-trihydroxyvitamin D2 [24(S), 25, 28(OH)3D2] and 24(R), 25, 26-trihydroxyvitamin D2 [24(R), 25, 26(OH)3D2], and the amounts of these two metabolites produced in the kidney of vitamin D2-intoxicated rat were about 3-5 times higher than those produced in the kidney of normal rat. Similar results were also obtained with rat kidney homogenates incubated with [3a-3H] 250HD2. Furthermore, we noted that the production of both 24(S), 25, 28(OH)3D2 and 24(R), 25, 26(OH)3D2 in the kidney homogenates of vitamin D2-intoxicated rats increased with the time of incubation and then subsequently decreased. The decrease in both 24(5), 25, 28(OH)3D2 and 24(R), 25, 26(OH)3D2 coincided with an increase in the fraction of total radioactivity distributed in the aqueous phase of the kidney homogenates. This finding suggested the possibility of further metabolism of 24(S), 25, 28(OH)3D2 and 24(R), 25, 26(OH)3D2 into polar water-soluble metabolite(s). We then measured the radioactivity in the aqueous phase of kidney homogenates of both normal and vitamin D2-intoxicated rats incubated with [3α-3H]25OHD2. It was noted that the amount of radioactivity in the aqueous phase of kidney homogenates of vitamin D2-intoxicated rats is higher than that present in the aqueous phase of kidney homogenates of normal rats. Thus, our study provides evi-dence for the first time for the formation of both 24(S), 25, 28(OH)3D2 and 24(R), 25, 26(OH)3D2 under physiological conditions, and the possibility of their further metabolism into as yet unidentified polar water-soluble metabolite(s). As the formation of all these metabolites is increased in the kidney of vitamin D2-intoxicated rats when compared to normal rats, it appears that the increased rate of metabolism of 25OHD2 during hypervitaminosis D2 plays a significant role in the deactivation of 25OHD2.
ISSN:0301-4800
1881-7742
DOI:10.3177/jnsv.46.222