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.     

Mapping the RNA binding sites for human immunodeficiency virus type-1 gag and NC proteins within the complete HIV-1 and -2 untranslated leader regions

Encapsidation of HIV-1 genomic RNA is mediated by specific interactions between the RNA packaging signal and the Gag protein. During maturation of the virion, the Gag protein is processed into smaller fragments, including the nucleocapsid (NC) domain which remains associated with the viral genomic RNA. We have investigated the binding of glutathione- S -transferase (GST) Gag and NC fusion proteins from HIV-1, to the entire HIV-1 and -2 leader RNAencompassing the packaging signal. We have mapped the binding sites at conditions where only about two complexes are formed and find that GST-Gag and GST-NC fusion proteins bind specifically to discrete sites within the leader. Analysis of the HIV-1 leader indicated that GST-Gag strongly associates with the PSI stem-loop and to a lesser extent with regions near the primer binding site. GST-NC binds the same regions but with reversed preferences. The HIV-1 proteins also interact specifically with the 5'-leader of HIV-2 and the major site of interaction mapped to a stem-loop, with homology to the HIV-1 PSI stem-loop structure. The different specificities of Gag and NC may reflect functionally distinct roles in the viral replication, and suggest that the RNA binding specificity of NC is modulated by its structural context.     

Identification of individual nucleotides in the bacterial ribonuclease P ribozyme adjacent to the pre-tRNA cleavage site by short-range photo-cross-linking

The bacterial RNase P ribozyme is a site-specific endonuclease that catalyzes the removal of pre-tRNA leader sequences to form the 5' end of mature tRNA. While several specific interactions between enzyme and substrate that direct this process have been determined, nucleotides on the ribozyme that interact directly with functional groups at the cleavage site are not well-defined. To identify individual nucleotides in the ribozyme that are in close proximity to the pre-tRNA cleavage site, we introduced the short-range photoaffinity cross-linking reagent 6-thioguanosine (s6G) at position +1 of tRNA and position -1 in a tRNA bearing a one-nucleotide leader sequence [tRNA(G-1)] and examined cross-linking in representatives of the two structural classes of bacterial RNase P RNA (from Escherichia coli and Bacillus subtilis). These photoagent-modified tRNAs bind with similar high affinity to both ribozymes, and the substrate bearing a single s6G upstream of the cleavage (-1) site is cleaved accurately. Interestingly, s6G at position +1 of tRNA cross-links with high efficiency to homologous positions in J5/15 in both E. coli and B. subtilis RNase P RNAs, while s6G at position -1 of tRNA(G-1) cross-links to homologous nucleotides in J18/2. Both cross-links are detected over a range of ribozyme and substrate concentrations, and importantly, ribozymes cross-linked to position -1 of tRNA(G-1) accurately cleave the covalently attached substrate. These data indicate that the conserved guanosine at the 5' end of tRNA is adjacent to A248 (E. coli) of J5/15, while the base upstream of the substrate phosphate is adjacent to G332 (E. coli) of J18/2 and, along with available biochemical data, suggest that these nucleotides play a direct role in binding the substrate at the cleavage site.