Direct evidence is presented for a conformational switch in 16S ribosomal RNA (rRNA) that affects tRNA binding to the ribosome and decoding of messenger RNA (mRNA). These data support the hypothesis that dynamic changes in rRNA structure occur during translation. The switch involves two alternating base-paired arrangements apparently facilitated by ribosomal proteins S5 and S12, and produces significant changes in the rRNA structure. Chemical probing shows reciprocal enhancements or protections at sites in 16S rRNA that are at or very near sites that were previously crosslinked to mRNA. These data indicate that the switch affects codon-anticodon arrangement and proper selection of tRNA at the ribosomal A site, and that the switch is a fundamental mechanism in all ribosomes.
Retroviruses encapsidate their genome as a dimer of homologous RNA molecules noncovalently linked close to their 59 ends. The dimerization initiation site (DIS) of human immunodeficiency virus type 1 (HIV-1) RNA is a hairpin structure that contains in the loop a 6-nt self-complementary sequence flanked by two 59 and one 39 purines. The self-complementary sequence, as well as the flanking purines, are crucial for dimerization of HIV-1 RNA, which is mediated by formation of a "kissing-loop" complex between the DIS of each monomer. Here, we used chemical modification interference, lead-induced cleavage, and three-dimensional modeling to compare dimerization of subtype A and B HIV-1 RNAs. The DIS loop sequences of these RNAs are AGGUGCACA and AAGCGCGCA, respectively. In both RNAs, ethylation of most but not all phosphate groups in the loop and methylation of the N7 position of the G residues in the self-complementary sequence inhibited dimerization. These results demonstrate that small perturbations of the loop structure are detrimental to dimerization. Conversely, methylation of the N1 position of the first and last As in the loop were neutral or enhanced dimerization, a result consistent with these residues forming a noncanonical sheared base pair. Phosphorothioate interference, lead-induced cleavage, and Brownian-dynamics simulation revealed an unexpected difference in the dimerization mechanism of these RNAs. Unlike subtype B, subtype A requires binding of a divalent cation in the loop to promote RNA dimerization. This difference should be taken into consideration in the design of antidimerization molecules aimed at inhibiting HIV-1 replication.
Translation initiation factor IF3 is an essential bacterial protein, consisting of two domains (IF3C and IF3N) separated by a linker, which interferes with ribosomal subunit association, promotes codon-anticodon interaction in the P site, and ensures translation initiation fidelity. Using time-resolved chemical probing, we followed the dynamic binding path of IF3 on the 30S subunit and its release upon 30S-50S association. During binding, IF3 first contacts the platform (near G700) of the 30S subunit with the C domain and then the P-decoding region (near A790) with its N domain. At equilibrium, attained within less than a second, both sites are protected, but before reaching binding equilibrium, IF3 causes additional transient perturbations of both the platform edge and the solvent side of the subunit. Upon 30S-50S association, IF3 dissociates concomitantly with the establishment of the 30S-50S bridges, following the reverse path of its binding with the IF3N-A790 interaction being lost before the IF3C-G700 interaction.
An essential step in the replication cycle of all retroviruses is the dimerization of genomic RNA prior to or during budding and maturation of the viral particle. In HIV-1 a 5′ leader region site referred to as stem-loop1 (SL1) promotes RNA dimerization in vitro and influences dimerization in vivo. In HIV-2, two sequences promote dimerization of RNA fragments in vitro: the 5′-end of the primerbinding site (PBS) and a stem loop homologous to the HIV-1 SL1 sequence. Because HIV-2 RNA constructs of different lengths use these two dimerization signals disproportionately, we hypothesized that other sequences could modulate their relative utilization. Here, we characterized the influence of sequences upstream and downstream of the major splice donor site on the formation of HIV-2 RNA dimers in vitro using a variety of RNA constructs and dimerization/electrophoresis protocols. We first assayed the formation of loose or tight dimers for 1-444 and 1-561 model RNAs. Although both RNAs could form PBS-dependent loose dimers, the 1-561 RNA was unable to make SL1-dependent tight dimers. Using RNAs truncated at their 5′ and/or 3′ ends and by making compensatory base substitutions we found that two elements interfere with the formation of SL1-dependent tight dimers. The cores of these elements are located at nucleotides 189-196 and 543-550. Our results suggest that base pairing between these sequences prevents the formation of SL1- † This research was supported by the National Institutes of Health grant number AI45388 to J.S.L.
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