The diploid genome of all retroviruses is made of two homologous copies of RNA intimately associated near their 5' end, in a region called the dimer linkage structure. Dimerizatlon of genomic RNA is thought to be important for crucial functions of the retroviral life cycle (reverse transcription, translation, encapsidation). Previous in vitro studies mapped the dimer linkage structure of human immunodeficiency virus type 1 (HIV-1) in a region downstream of the splice donor site, containing conserved purine tracts that were postulated to mediate dimerization, through purine quartets. However, we recently showed that dimerization of HIV-1 RNA also involves sequences upstream of the splice donor site. Here, we used chemical modification interference to identify nucleotides that are required in unmodified form for dimerization of a RNA fragment containing nucleotides A ubiquitous property of retroviruses is that their genonme consists of two homologous copies of single-stranded RNA (1). Electron microscopy showed that these two RNAs are joined together in an apparent parallel orientation by a structure called the dimer linkage structure (DLS) located near their 5' end (2-5). Dimerization of genomic RNA is considered to control several essential steps of the retroviral life cycle. First, it was proposed to act as a positive signal for encapsidation (6,7). Second, it was suggested to downregulate the translation ofthe gag gene in Rous sarcoma virus (RSV) and human immunodeficiency virus type 1 (HIV-1) (8, 9). Third, the dimeric nature of the retroviral genome is thought to be of importance in the process of reverse transcription and recombination since it may account for the first strand transfer and template switching during proviral DNA synthesis (10-14). Therefore, dimerization of genomic RNA most likely represents a potential target for the design of antiviral drugs against HIV and other retroviruses.However, the process of dimerization is still poorly understood. Dimerization of synthetic fragments containing the (29). Again, probing data indicate that the same structure is found in synthetic RNA fragments (9,30) and in genomic RNA extracted from infected cells (29).In HIV-1, several reports showed that a RNA region of -100 nucleotides located downstream of the splice donor (SD) site is able to dimerize in vitro (6,(21)(22)(23)(24). This region that includes important components of the packaging signal (29,31,32) was assumed to contain the putative DLS. However, the mechanism of dimerization is still a subject of controversy. In an initial study, we proposed that polypurine tracts, the only common motifs found in the putative dimerization-encapsidation region of most retroviral RNAs, may be involved in the dimerization process through the formation of quartets involving both guanines and adenines (21). This concept has been disputed by recent reports suggesting that dimers formed with short RNA restricted to the postulated DLS are stabilized by quartets containing only guanines (23,24). However, the di...
The influenza A virus genome consists of eight viral RNAs (vRNAs) that form viral ribonucleoproteins (vRNPs). Even though evidence supporting segment-specific packaging of vRNAs is accumulating, the mechanism ensuring selective packaging of one copy of each vRNA into the viral particles remains largely unknown. We used electron tomography to show that the eight vRNPs emerge from a common ‘transition zone’ located underneath the matrix layer at the budding tip of the virions, where they appear to be interconnected and often form a star-like structure. This zone appears as a platform in 3D surface rendering and is thick enough to contain all known packaging signals. In vitro, all vRNA segments are involved in a single network of intermolecular interactions. The regions involved in the strongest interactions were identified and correspond to known packaging signals. A limited set of nucleotides in the 5′ region of vRNA 7 was shown to interact with vRNA 6 and to be crucial for packaging of the former vRNA. Collectively, our findings support a model in which the eight genomic RNA segments are selected and packaged as an organized supramolecular complex held together by direct base pairing of the packaging signals.
RNA-RNA interactions govern a number of biological processes. Several RNAs, including natural sense and antisense RNAs, interact by means of a two-step mechanism: recognition is mediated by a loop-loop complex, which is then stabilized by formation of an extended intermolecular duplex. It was proposed that the same mechanism holds for dimerization of the genomic RNA of human immunodeficiency virus type 1 (HIV-1), an event thought to control crucial steps of HIV-1 replication. However, whereas interaction between the partially self-complementary loop of the dimerization initiation site (DIS) of each monomer is well established, formation of the extended duplex remained speculative. Here we first show that in vitro dimerization of HIV-1 RNA is a specific process, not resulting from simple annealing of denatured molecules. Next we used mutants of the DIS to test the formation of the extended duplex. Four pairs of transcomplementary mutants were designed in such a way that all pairs can form the loop-loop "kissing" complex, but only two of them can potentially form the extended duplex. All pairs of mutants form heterodimers whose thermal stability, dissociation constant, and dynamics were analyzed. Taken together, our results indicate that, in contrast with the interactions between natural sense and antisense RNAs, no extended duplex is formed during dimerization of HIV-1 RNA. We also showed that 55-mer sense RNAs containing the DIS are able to interfere with the preformed HIV-1 RNA dimer.
In addition to genomic RNA, HIV-1 particles package cellular and spliced viral RNAs. In order to determine the encapsidation mechanisms of these RNAs, we determined the packaging efficiencies and specificities of genomic RNA, singly and fully spliced HIV mRNAs and different host RNAs species: 7SL RNA, U6 snRNA and GAPDH mRNA using RT-QPCR. Except GAPDH mRNA, all RNAs are selectively encapsidated. Singly spliced RNAs, harboring the Rev-responsible element, and fully spliced viral RNAs, which do not contain this motif, are enriched in virions to similar levels, even though they are exported from the nucleus by different routes. Deletions of key motifs (SL1 and/or SL3) of the packaging signal of genomic RNA indicate that HIV and host RNAs are encapsidated through independent mechanisms, while genomic and spliced viral RNA compete for the same trans-acting factor due to the presence of the 5′ common exon containing the TAR, poly(A) and U5-PBS hairpins. Surprisingly, the RNA dimerization initiation site (DIS/SL1) appears to be the main packaging determinant of genomic RNA, but is not involved in packaging of spliced viral RNAs, suggesting a functional interaction with intronic sequences. Active and selective packaging of host and spliced viral RNAs provide new potential functions to these RNAs in the early stages of the virus life cycle.
With the increasing interest of RNAs in regulating a range of cell biological processes, very little is known about the structure of RNAs in tissue culture cells. We focused on the 5 -untranslated region of the human immunodeficiency virus type 1 RNA genome, a highly conserved RNA region, which contains structural domains that regulate key steps in the viral replication cycle. Up until now, structural information only came from in vitro studies. Here, we developed chemical modification assays to test nucleotide accessibility directly in infected cells and viral particles, thus circumventing possible biases and artifacts linked to in vitro assays. The secondary structure of the 5 -untranslated region in infected cells points to the existence of the various stemloop motifs associated to distinct functions, proposed from in vitro probing, mutagenesis, and phylogeny. However, compared with in vitro data, subtle differences were observed in the dimerization initiation site hairpin, and none of the proposed long range interactions were observed between the functional domains. Moreover, no global RNA rearrangement was observed; structural differences between infected cells and viral particles were limited to the primer binding site, which became protected against chemical modification upon tRNA 3 Lys annealing in virions and to the main packaging signal. In addition, our data suggested that the genomic RNA could already dimerize in the cytoplasm of infected cells. Taken together, our results provided the first analysis of the dynamic of RNA structure of the human immunodeficiency virus type 1 RNA genome during virus assembly ex vivo.
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