Abstract EN:

The amino acid selenocysteine is encoded by a UGA triplet which acts generally as a stop codon. A specialized machinery is used to incorporate this amino acid into selenoproteins, involving a specific stem-loop, termed SelenoCysteine Insertion Sequence (SECIS), and some protein factors. One of those is the SECIS Binding Protein 2 (SBP2), which is necessary for ribosome recognition of the UGA as the Sec codon. Using synthetic selenocysteine mRNAs and translational inhibitors, several steps of mRNA translation were analyzed. The data obtained allowed us to propose the following mechanism for selenocysteine insertion : during the transpeptidation step of elongation, SBP2 is bound to the ribosome; however, after transpeptidation, SBP2 leaves the ribosome and binds the SECIS in the pre-translocation step. We showed earlier that SBP2 binds specifically to the purified human 60S but not to the 40S ribosome subunits but the actual location was unknown. The SBP2•40S, SBP2•60S and SBP2•80S complexes were thus studied using crosslinking reagents. SBP2 did not crosslink to the 40S subunit in either the 40S•SBP2 or 80S•SBP2 complexes, correlating with the binding data. However, SBP2 crosslinks to the 60S subunit in either the free state or in the 80S ribosome. I next showed that the 28S rRNA contributes more to the crosslink than ribosomal proteins. This led us to use hydroxyl radical footprinting to study the molecular environment of SBP2 on the ribosome. According to the probing data, the binding of SBP2 to the human 60S subunit protects 2 helices in expansion segment 7 of the 28S rRNA. I proposed that the SBP2 binding site is located in the vicinity of the L7/L12 stalk.