Molecular biology of selenium with implications for its metabolism

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Molecular biology of selenium with implications for its metabolism

RF Burk
Department of Medicine, Vanderbilt University School of Medicine, Nashville, Tennessee 37232.

Selenium has a highly specific metabolism centered around its incorporation as selenocysteine into selenoproteins. An outline of this metabolism has emerged from recent molecular biological and biochemical studies of bacteria and animals. A unique tRNA, designated tRNA[Ser]Sec, is charged with L-serine, which is then converted through at least two steps to selenocysteine. With the aid of a unique translation factor, the selenocysteinyl-tRNA[Ser]Sec recognizes specific UGA codons in mRNA to insert selenocysteine into the primary structure of selenoproteins. Turnover of selenoproteins presumably liberates selenocysteine which is toxic in its free form. Selenocysteine beta-lyase catabolizes free selenocysteine and makes its selenium available for reuse. Proteins contain almost all the selenium in animals. Of the known selenoproteins, the glutathione peroxidases contain the most selenium. Cellular and plasma glutathione peroxidases are products of different genes but have 44% identity of amino acid sequence. There is evidence for other proteins of this family. Selenoprotein P is an unrelated protein with multiple selenocysteines in its primary structure. It contains most of the selenium in rat plasma. Studies of the regulation of cellular glutathione peroxidase by selenium have yielded conflicting results, but there is a strong suggestion that mRNA levels of the rodent liver glutathione peroxidase decrease in selenium deficiency. This could be a mechanism for directing selenium to the synthesis of other selenoproteins. Although present knowledge allows construction of an outline of selenium metabolism, several steps have not been characterized and little is known about mechanisms of its regulation.

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				W.-H. CHENG, Y. X. FU, J. M. PORRES, D. A. ROSS, and X. G. LEI Selenium-dependent cellular glutathione peroxidase protects mice against a pro-oxidant-induced oxidation of NADPH, NADH, lipids, and protein FASEB J, August 1, 1999; 13(11): 1467 - 1475. [Abstract] [Full Text]

				M. A. Beck, R. S. Esworthy, Y. Ho, and F. Chu Glutathione peroxidase protects mice from viral-induced myocarditis FASEB J, September 1, 1998; 12(12): 1143 - 1149. [Abstract] [Full Text]

				W.-H. Cheng, Y.-S. Ho, B. A. Valentine, D. A. Ross,, G. F. Combs Jr., and X. G. Lei Cellular Glutathione Peroxidase Is the Mediator of Body Selenium To Protect against Paraquat Lethality in Transgenic Mice J. Nutr., July 1, 1998; 128(7): 1070 - 1076. [Abstract] [Full Text] [PDF]

				W.-H. Cheng, Y.-S. Ho, D. A. Ross, B. A. Valentine, G. F. Combs Jr., and X. G. Lei Cellular Glutathione Peroxidase Knockout Mice Express Normal Levels of Selenium-Dependent Plasma and Phospholipid Hydroperoxide Glutathione Peroxidases in Various Tissues J. Nutr., August 1, 1997; 127(8): 1445 - 1450. [Abstract] [Full Text]

				W.-H. Cheng, Y.-S. Ho, D. A. Ross, Y. Han, G. F. Combs Jr., and X. G. Lei Overexpression of Cellular Glutathione Peroxidase Does Not Affect Expression of Plasma Glutathione Peroxidase or Phospholipid Hydroperoxide Glutathione Peroxidase in Mice Offered Diets Adequate or Deficient in Selenium J. Nutr., May 1, 1997; 127(5): 675 - 680. [Abstract] [Full Text] [PDF]

				H. Niwa, L. C. Harrison, H. J. DeAizpurua, and D. S. Cram Identification of Pancreatic {beta} Cell-Related Genes by Representational Difference Analysis Endocrinology, April 1, 1997; 138(4): 1419 - 1426. [Abstract] [Full Text] [PDF]

				S. Himeno, H. S. Chittum, and R. F. Burk Isoforms of Selenoprotein P in Rat Plasma. EVIDENCE FOR A FULL-LENGTH FORM AND ANOTHER FORM THAT TERMINATES AT THE SECOND UGA IN THE OPEN READING FRAME J. Biol. Chem., June 28, 1996; 271(26): 15769 - 15775. [Abstract] [Full Text] [PDF]

				J. Ortuno, G. Ros, M.J. Periago, C. Martinez, and G. Lopez Biodisponibilidad del selenio y metodos de evaluacion/Selenium bioavailability and methods of evaluation Food Science and Technology International, January 1, 1996; 2(3): 135 - 150. [PDF]

				M. Bj�rnstedt, M. Hamberg, S. Kumar, J. Xue, and A. Holmgren Human Thioredoxin Reductase Directly Reduces Lipid Hydroperoxides by NADPH and Selenocystine Strongly Stimulates the Reaction via Catalytically Generated Selenols J. Biol. Chem., May 19, 1995; 270(20): 11761 - 11764. [Abstract] [Full Text] [PDF]

				S Ringquist, D Schneider, T Gibson, C Baron, A Bock, and L Gold Recognition of the mRNA selenocysteine insertion sequence by the specialized translational elongation factor SELB. Genes & Dev., February 1, 1994; 8(3): 376 - 385. [Abstract] [PDF]

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Molecular biology of selenium with implications for its metabolism