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  • Title: Molecular and transport effects of 1,25-dihydroxyvitamin D3 in rat duodenum.
    Author: Bronner F, Lipton J, Pansu D, Buckley M, Singh R, Miller A.
    Journal: Fed Proc; 1982 Jan; 41(1):61-5. PubMed ID: 6895734.
    Abstract:
    The saturable component of transmural calcium transport in rat duodenum is transcellular, dependent on vitamin D, and can be evaluated by in situ gut loops or everted sacs. Vitamin D action at the molecular level can be studied by analyzing the response in terms of calcium-binding protein (CaBP; Mr congruent to 9000) biosynthesis to exogenous 1,25-dihydroxyvitamin D3 (1,25-(OH)2-D3). In vitamin D-replete animals, the CaBP response occurs within 1 h of intraperitoneal injection when the animals have been fed a high-calcium diet (III), but in 7 h if the animals have been fed a low-calcium diet(I). The latter response appears to be transcriptional, whereas the former seems posttranscriptional. In vitamin D-deficient animals, exogenous 1,25-(OH)2-D3 evokes a CaBP response that occurs 7-8 h after treatment and is transcriptional in nature. Calcium uptake by isolated duodenal cells can be stimulated by prior in vivo treatment with 1,25-(OH)2-D3. Peak response times parallel those found with CaBP biosynthesis, i.e., 3 h in cells from vitamin D-replete animals fed diet III, 7 h in cells from vitamin D-replete animals fed diet I, and 12 h in cells from vitamin D-deficient animal. Cycloheximide treatment appears to inhibit these responses. Moreover, everted sacs from vitamin D-replete animals fed diets III and I show an early and a delayed transport response, respectively. Studies with brush border membrane vesicles prepared from rat duodenum have shown calcium uptake to be vitamin D-dependent. Part of this uptake involves binding to the inner aspect of the membrane and may involve a high-affinity CaBP. Thus a major component of the action of vitamin D in stimulating calcium transport appears to involve protein synthesis. The time and molecular nature of these responses depend on the calcium intake and vitamin D status of the animals. A model of calcium movement through the intestinal cell is included.
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