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J Biol Chem, Vol. 273, Issue 43, 28533-28541, October 23, 1998
,§
From the A UGA codon and a selenocysteine insertion
sequence in the 3'-untranslated region are the only established
mRNA elements necessary for selenocysteine (Sec or U) incorporation
during translation. These two elements, however, do not universally
confer efficient Sec incorporation. The objective of this study was to
systematically examine the effect of UGA codon position on efficiency
of Sec insertion. In a glutathione peroxidase-1 (F-GPX1) expression
vector, the UGA at the native position (U47) was mutated to a cysteine codon, and codons for Ser-7, Ser-12, Ser-18, Ser-29, Ser-45, Ser-93, Cys-154, Val-172, Ser-178, and Ser-195 were individually mutated to UGA
and transiently expressed in COS-7 cells. 75Se
incorporation at the 11 positions was 31, 72, 54, 105, 90, 100, 146, 135, 13, 11, and 43%, respectively, of 75Se incorporation
at U47, suggesting that Sec is more efficiently incorporated at UGA
codons positioned in the middle of the coding region rather than close
to the 5' or 3' ends. Ribonuclease protection showed that these
differences were not due to differences in mRNA level. When the
green fluorescence protein (GFP) coding region was placed in-frame at
the 5' or 3' ends of the coding region in F-GPX1 to produce chimeric
50-51-kDa GFP/GPX1 proteins, Sec incorporation at UGA codons, formerly
close to the 5' or 3' ends, was increased to levels comparable to the
UGA at U47. Insertion of GFP after the UAA-stop was just as effective
in increasing Sec insertion efficiency as GFP inserted before the stop.
These studies used a recombinant expression model that incorporated Sec
at non-native UGA codons at rates equal to those of endogenous glutathione peroxidase-1 and showed that the efficiency of Sec incorporation can be modulated by UGA position; Sec incorporation at
high efficiency appears to require that the UGA be >21 nucleotides from the AUG-start and >204 nucleotides from the selenocysteine insertion sequence element.
Nutritional Sciences Program and
§ Department of Biochemistry, University of Missouri,
Columbia, Missouri 65211
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