Structure and dimerization of HIV-1 kissing loop aptamers.

Dimerization of two homologous strands of genomic RNA is an essential feature of the retroviral replication cycle. In HIV-1, genomic RNA dimerization is facilitated by a conserved stem-loop structure located near the 5' end of the viral RNA called the dimerization initiation site (DIS). The DIS loop is comprised of nine nucleotides, six of which define an autocomplementary sequence flanked by three conserved purine residues. Base- pairing between the loop sequences of two copies of genomic RNA is necessary for efficient dimerization. We previously used in vitro evolution to investigate a possible structural basis for the marked sequence conservation of the DIS loop. In this study, chemical structure probing, measurements of the apparent dissociation constants, and computer structure analysis of dimerization-competent aptamers were used to analyze the dimers' structure and binding. The selected aptamers were variants of the naturally occurring A and B subtypes. The data suggest that a sheared base-pair closing the loop of the DIS is important for dimerization in both subtypes. On the other hand, the open or closed state of the last base-pair in the stem differed in the two subtypes. This base-pair appeared closed in the subtype A DIS dimer and open in subtype B. Finally, evidence for a cross-talk between nucleotides 2, 5, and 6 was found in some, but not all, loop contexts, indicating some structural plasticity depending on loop sequence. Discriminating between the general rules governing dimer formation and the particular characteristics of individual DIS aptamers helps to explain the affinity and specificity of loop-loop interactions and could provide the basis for development of drugs targeted against the dimerization step during retroviral replication.

Identification of the in vitro HIV-2/SIV RNA dimerization site reveals striking differences with HIV-1.

Although their genomes cannot be aligned at the nucleotide level, the HIV-1/SIVcpz and the HIV-2/SIVsm viruses are closely related lentiviruses that contain homologous functional and structural RNA elements in their 5'-untranslated regions. In both groups, the domains containing the trans-activating region, the 5'-copy of the polyadenylation signal, and the primer binding site (PBS) are followed by a short stem-loop (SL1) containing a six-nucleotide self-complementary sequence in the loop, flanked by unpaired purines. In HIV-1, SL1 is involved in the dimerization of the viral RNA, in vitro and in vivo. Here, we tested whether SL1 has the same function in HIV-2 and SIVsm RNA. Surprisingly, we found that SL1 is neither required nor involved in the dimerization of HIV-2 and SIV RNA. We identified the NarI sequence located in the PBS as the main site of HIV-2 RNA dimerization. cis and trans complementation of point mutations indicated that this self-complementary sequence forms symmetrical intermolecular interactions in the RNA dimer and suggested that HIV-2 and SIV RNA dimerization proceeds through a kissing loop mechanism, as previously shown for HIV-1. Furthermore, annealing of tRNA(3)(Lys) to the PBS strongly inhibited in vitro RNA dimerization, indicating that, in vivo, the intermolecular interaction involving the NarI sequence must be dissociated to allow annealing of the primer tRNA.

Comparison of rRNA cleavage by complementary 1,10-phenanthroline-Cu(II)- and EDTA-Fe(II)-derivatized oligonucleotides.

The chemical nucleases 1,10-phenanthroline-Cu(II) and EDTA-Fe(II), have proven to be valuable tools for structural analysis of nucleic acids. Both have found applications in footprinting and directed proximity studies of DNA and RNA. Derivatives of each that provide for tethering to nucleic acid or protein are commercially available, allowing their widespread use for structural analysis of macromolecules. Although their applications are somewhat overlapping, differences in their cleavage mechanisms and chemical properties allow them to provide distinct and complementary structural information. The purpose of this study is to compare directly the cleavage patterns of tethered 1,10-phenanthroline-Cu(II) and EDTA-Fe(II) complexes within a similar experimental system. Here, the region surrounding nucleotide 1400 of 16S rRNA from Escherichia coli serves as a substrate for chemical cleavage directed by a derivatized complementary oligonucleotide. This region of rRNA is known to be involved in the decoding of mRNA during translation. The results of this study provide evidence in support of the mechanistic differences previously established for EDTA-Fe(II) and 1,10-phenathroline-Cu(II). The delocalized cleavage envelope produced by EDTA-Fe(II) cleavage suggests the involvement of a diffusible reactive species. On the other hand, rRNA cleavage induced by the tethered 1,10-phenanthroline-Cu(II) complex appears localized to the proximity of the chemical nuclease under normal conditions, although the production of an unknown diffusible species appears to occur during long reaction times.

Convergence of natural and artificial evolution on an RNA loop-loop interaction: the HIV-1 dimerization initiation site.

Loop-loop interactions among nucleic acids constitute an important form of molecular recognition in a variety of biological systems. In HIV-1, genomic dimerization involves an intermolecular RNA loop-loop interaction at the dimerization initiation site (DIS), a hairpin located in the 5' noncoding region that contains an autocomplementary sequence in the loop. Only two major DIS loop sequence variants are observed among natural viral isolates. To investigate sequence and structural constraints on genomic RNA dimerization as well as loop-loop interactions in general, we randomized several or all of the nucleotides in the DIS loop and selected in vitro for dimerization-competent sequences. Surprisingly, increasing interloop complementarity above a threshold of 6 bp did not enhance dimerization, although the combinations of nucleotides forming the theoretically most stable hexanucleotide duplexes were selected. Noncanonical interactions contributed significantly to the stability and/or specificity of the dimeric complexes as demonstrated by the overwhelming bias for noncanonical base pairs closing the loop and covariations between flanking and central loop nucleotides. Degeneration of the entire loop yielded a complex population of dimerization-competent sequences whose consensus sequence resembles that of wild-type HIV-1. We conclude from these findings that the DIS has evolved to satisfy simultaneous constraints for optimal dimerization affinity and the capacity for homodimerization. Furthermore, the most constrained features of the DIS identified by our experiments could be the basis for the rational design of DIS-targeted antiviral compounds.

Dimerization of HIV-1 genomic RNA of subtypes A and B: RNA loop structure and magnesium binding.

Retroviruses encapsidate their genome as a dimer of homologous RNA molecules noncovalently linked close to their 5' 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 5' and one 3' 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.

Oligonucleotide-mediated inhibition of genomic RNA dimerization of HIV-1 strains MAL and LAI: a comparative analysis.

An essential step in the replication cycle of retroviruses is the dimerization of two copies of the genomic RNA. In vitro and in vivo studies have demonstrated that dimerization is mediated at least partially by RNA-RNA interactions. In HIV-1, the cis-element most important for dimerization is the dimerization initiation site (DIS), a stem-loop structure with an autocomplementary loop located between the primer binding site and the splice donor site in the 5' leader region of genomic RNA. We have studied the inhibition of dimerization of RNA corresponding to the first 615 nt of HIV-1 strains MAL and LAI in vitro using RNA and DNA oligonucleotides. The oligonucleotides were identical to or complementary to the DIS of the MAL and LAI strains, which are representative of the two most common DIS motifs found in natural isolates. The loop sequence of the DIS of the MAL isolate is AGGUGCACA, and that of the LAI sequence is AAGCGCGCA (the autocomplementary sequences are GUGCAC and GCGCGC, respectively). Several of the oligonucleotides were very efficient inhibitors of dimerization. However, homologous oligonucleotides displayed vastly different inhibition efficiencies between the two strains despite relatively modest sequence differences. Some of the oligonucleotides bound the viral RNA via a loop-loop interaction alone, whereas others recruited stem nucleotides to form an extended duplex even in the absence of loop complementarity. Furthermore, oligonucleotide inhibition was ineffective at low temperature, suggesting that a conformational change in the DIS is necessary for disruption of the dimeric structure of the DIS or binding of oligonucleotide or both.

A conformational switch in Escherichia coli 16S ribosomal RNA during decoding of messenger RNA.

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.

Genetic probes of ribosomal RNA function.

We have used a genetic approach to uncover the functional roles of rRNA in protein synthesis. Mutations were constructed in a cloned rrn operon by site-directed mutagenesis or isolated by genetic selections following random mutagenesis. We have identified mutations that affect each step in the process of translation. The data are consistent with the results of biochemical and phylogenetic analyses but, in addition, have provided novel information on regions of rRNA not previously investigated.

Genetic and comparative analyses reveal an alternative secondary structure in the region of nt 912 of Escherichia coli 16S rRNA.

Mutations at position 912 of Escherichia coli 16S rRNA result in two notable phenotypes. The C-->U transition confers resistance to streptomycin, a translational-error-inducing antibiotic, while a C-->G transversion causes marked retardation of cell growth rate. Starting with the slow-growing G912 mutant, random mutagenesis was used to isolate a second site mutation that restored growth nearly to the wild-type rate. The second site mutation was identified as a G-->C transversion at position 885 in 16S rRNA. Cells containing the G912 mutation had an increased doubling time, abnormal sucrose gradient ribosome/subunit profile, increased sensitivity to spectinomycin, dependence upon streptomycin for growth in the presence of spectinomycin, and slower translation rate, whereas cells with the G912/C885 double mutation were similar to wild type in these assays. Comparative analysis showed there was significant covariation between positions 912 and 885. Thus the second-site suppressor analysis, the functional assays, and the comparative data suggest that the interaction between nt 912 and nt 885 is conserved and necessary for normal ribosome function. Furthermore, the comparative data suggest that the interaction extends to include G885-G886-G887 pairing with C912-U911-C910. An alternative secondary structure element for the central domain of 16S rRNA is proposed.

Evidence for a conformational change in the exit site of the Escherichia coli ribosome upon tRNA binding.

The exit (E) site of the Escherichia coli ribosome was investigated using oligodeoxyribonucleotides complementary to single-stranded regions of ribosomal RNA suggested to be involved in tRNA binding in the E site [Moazed, D., & Noller, H. (1989) Cell 57, 585-597]. Radiolabeled DNA oligomers (probes) were hybridized in situ to complementary sites on the ribosomal RNA of ribosomes or ribosomal subunits, and the effects of simultaneous tRNA or antibiotic binding on probe binding were measured using a nitrocellulose filtration binding assay. Site specificity of probe binding was assured using ribonuclease H to cleave the ribosomal RNA at the site of probe binding. When 50S subunits were hybridized with a probe spanning bases 2109-2119 and deacylated tRNA was added incrementally, probe binding decreased, suggesting that the probe and tRNA competed for the same binding site or that tRNA was allosterically affecting the probe binding site. When 70S ribosomes were substituted for 50S subunits, probe binding to this site initially increased and then decreased at higher concentrations of deacylated tRNA. Titrating probe-ribosome complexes with acylated tRNA, N-acetyl-acylated tRNA, tetracycline, or chloramphenicol had no effect on probe binding. The data presented provide evidence for tRNA/rRNA interaction at or near the E site of the E. coli ribosome and suggest that a conformational change occurs in the E site when deacylated tRNA is bound to the P site. The data suggest that deacylated tRNA in the P site serves as a translocational trigger by causing the E site to change conformations, making it more available for tRNA (and probe) binding and therefore promoting translocation.(ABSTRACT TRUNCATED AT 250 WORDS)

Identification of a rRNA/chloramphenicol interaction site within the peptidyltransferase center of the 50 S subunit of the Escherichia coli ribosome.

We have used oligodeoxyribonucleotide probes to investigate possible interactions between chloramphenicol and portions of the rRNA contained within the peptidyltransferase center of the Escherichia coli ribosome. Oligodeoxyribonucleotide probes complementary to bases 2448-2454, 2468-2482, and 2497-2505 of 23 S rRNA were hybridized to 50 S subunits in situ. Probe binding was qualitatively assessed by sucrose gradient centrifugation. Each probe was shown to bind specifically with its intended binding site through digestion of the rRNA within the RNA/DNA hetero-duplexes with RNase H and analysis of the digestion fragments using gel electrophoresis. Competitive binding experiments were conducted between each probe and the antibiotics chloramphenicol and erythromycin. The binding of a probe complementary to bases 2497-2505 was attenuated by 70% upon the binding of chloramphenicol. A probe complementary to bases 2468-2482 showed an increase in binding of 14% while binding of a probe complementary to bases 2448-2454 was not affected by chloramphenicol binding. Erythromycin did not affect the binding of any of these probes to 50 S subunits. These results suggest that bases within the 2497-2505 region of 23 S rRNA in E. coli may be involved in a chloramphenicol/rRNA interaction.