The special elongation factor SelB of Escherichia coli promotes selenocysteine incorporation into formate dehydrogenases. This is thought to be achieved through simultaneous binding to selenocysteyl-tRNA Sec and, in the case of formate dehydrogenase H, to an fdhF mRNA hairpin structure 3 adjacent to the UGA selenocysteine codon. By in vitro selection, novel RNA sequences (''aptamers''), which can interact tightly and specifically with SelB, were isolated from an RNA library. The library was comprised of mutagenized variants of the wild-type fdhF mRNA hairpin. One-half of the selected sequences contained the apical stem-loop of the fdhF mRNA hairpin highly conserved. Some of the aptamers showed deviations in the primary sequence within this region of the wild-type fdhF hairpin motif while still binding with high affinity to SelB. Binding studies performed with truncated versions of SelB revealed that aptamers binding to different sites on the protein have been selected. To dissect SelB binding to the fdhF hairpin from the overall biological function of this complex, four selected aptamers were analyzed in vivo for UGA readthrough in a lacZ fusion construct. Among these, one promoted UGA readthrough in vivo. Three of the aptamers, however, were drastically reduced or unable to replace the fdhF mRNA hairpin in vivo, despite the similar secondary structure and binding affinities of these RNAs compared with the wild-type motif. This finding implies functions of the fdhF hairpin that go beyond the mere tethering of selenocysteyl-tRNA Sec to the UGA codon.
Decoding of the UGA codon in mRNAs for selenoproteins as selenocysteine requires interaction of the translation factor SelB with an mRNA structure, the SECIS element. A genetic analysis of this interaction was performed by selecting for intergenic suppressor mutations in selB which counteracted the detrimental effect of defined mutations in the SECIS element. Both allele-nonspecific and allele-specific mutations, as judged by readthrough of the UGA into the LacZ-encoding segment of fdhF'-'lacZ fusions and by incorporation of selenium, were isolated. selB genes from ten suppressor mutants were sequenced and the corresponding mutations were localized to five positions within the protein. Four of the suppressors had amino acid exchanges within a 23-amino acid stretch in domain 4b of SelB, which probably represent sites of contact between the protein and the mRNA. A fifth mutation was localized in domain 4a of SelB; it promoted allele-nonspecific readthrough. Since a truncated SelB species lacking domain 4b did not show complex formation with the SECIS element, we speculate that the latter mutation affects the interaction between the tRNA-binding and the mRNA-binding domains. None of the SelB variants was able to promote UGA readthrough when major structural changes that altered the length of the helical part or enlarged the apical loop were introduced into the SECIS element. The results obtained also show that novel pairs of SelB/SECIS derivatives can be generated which may be useful for the targeted insertion of selenocysteine into proteins.
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