Possible role of dimerization in human immunodeficiency virus type 1 genome RNA packaging

The dimer initiation site/dimer linkage sequence (DIS/DLS) region in the human immunodeficiency virus type 1 (HIV-1) RNA genome is suggested to play important roles in various steps of the virus life cycle. However, due to the presence of a putative DIS/DLS region located within the encapsidation signal region (E/psi), it is difficult to perform a mutational analysis of DIS/DLS without affecting the packaging of RNA into virions. Recently, we demonstrated that duplication of the DIS/DLS region in viral RNA caused the production of partially monomeric RNAs in virions, indicating that the region indeed mediated RNA-RNA interaction. We utilized this system to assess the precise location of DIS/DLS in the 5' region of the HIV-1 genome with minimum effect on RNA packaging. We found that the entire lower stem of the U5/L stem-loop was required for packaging, whereas the region important for dimer formation was only 10 bases long within the lower stem of the U5/L stem-loop. The R/U5 stem-loop was required for RNA packaging but was completely dispensable for dimer formation. The SL1 lower stem was important for both dimerization and packaging, but surprisingly, deletion of the palindromic sequence at the top of the loop only partially affected dimerization. These results clearly indicated that the E/psi of HIV-1 is much larger than the DIS/DLS and that the primary DIS/DLS is completely included in the E/psi. Therefore, it is suggested that RNA dimerization is a part of RNA packaging, which requires multiple steps.     

A study of the dimer formation of Rous sarcoma virus RNA and of its effect on viral protein synthesis in vitro.

The genetic material of all retroviruses examined so far is an RNA dimer where two identical RNA subunits are joined at their 5' ends by a structure named dimer linkage structure (DLS). Since the precise location and structure of the DLS as well as the mechanism and role(s) of RNA dimerization remain unclear, we analysed the dimerization process of Rous sarcoma virus (RSV) RNA. For this purpose we set up an in vitro model for RSV RNA dimerization. Using this model RSV RNA was shown to form dimeric molecules and this dimerization process was greatly activated by nucleocapsid protein (NCp12) of RSV. Furthermore, RSV RNA dimerization was performed in the presence of complementary 5'32P-DNA oligomers in order to probe the monomer and dimer forms of RSV RNA. Data indicated that the DLS of RSV RNA probably maps between positions 544-564 from the 5' end. In an attempt to define sequences needed for the dimerization of RSV RNA, deletion mutageneses were generated in the 5' 600 nt. The results showed that the dimer promoting sequences probably are located within positions 208-270 and 400-600 from the 5' end and hence possibly encompassing the cis-acting elements needed for the specific encapsidation of RSV genomic RNA. Also it is reported that synthesis of the polyprotein precursor Pr76gag is inhibited upon dimerization of RSV RNA. These results suggest that dimerization and encapsidation of genome length RSV RNA might be linked in the course of virion formation since they appear to be under the control of the same cis elements, E and DLS, and the trans-acting factor nucleocapsid protein NCp12.     

Structure of the HIV-1 5' untranslated region dimer alone and in complex with gold nanocolloids: support of a TAR-TAR-containing 5' dimer linkage site (DLS) and a 3' DIS-DIS-containing DLS

The formation of a genomic RNA dimer is critical for the HIV-1 replication cycle, and dimerization is known to initiate within the 5'UTR (5' untranslated region) of the viral RNA. However, the 5'UTR constitutes the 335 terminal nucleotides, and because of this considerable size, it has been difficult to study the global structure using conventional structural methods. Here, the atomic force microscope has been used to directly visualize the dimer formed from RNAs including HIV-1 nucleotides 1-744. Gold nanocolloids were deposited on the primer binding site regions in the dimer as an internal control. The dimer showed distinct ring morphology with up to two gold nanocolloids deposited within the ring and one or two strands extending from the ring. This morphology implies a dimer including a DIS-DIS (dimerization initiation site)-containing 3' dimer linkage site (DLS) and a TAR-TAR (trans-activation region)-containing 5'DLS. Furthermore, the dimer was formed under the influence of Mg(2+) and was imaged with an atomic force microscope under buffer conditions. The overall ring morphology containing a 5'DLS and a 3'DLS with one or two strands extending from it was conserved in these atomic force microscopy images. This indicates that the observed dimer morphology is physiologically significant. Moreover, evidence of multiple dimer interstrand contacts downstream of the major splice donor were observed, which indicates a component in the selection of full-length genomic RNA in dimer formation during virion packaging.     

Alteration of location of dimer linkage sequence in retroviral RNA: little effect on replication or homologous recombination.

Retrovirus particles contain a dimer of retroviral genomic RNA. A defined region of the retrovirus genome has previously been shown to be important for both dimerization and encapsidation. To study the importance of the position of this encapsidation and dimerization signal for retroviral replication and homologous recombination, we used a previously described spleen necrosis virus-based helper cell system. This system allows retroviral vectors with multiple genetic markers to be studied after a single cycle of retroviral replication. The sequence responsible for dimerization, the encapsidation/dimer linkage sequence (E/DLS), was moved from its normal location near the 5' end of the retroviral genome to a location near the 3' end of the genome. We characterized four pairs of retroviral vectors: (i) with both E/DLSs at the 5' ends of the genomes, (ii) with both E/DLSs at the 3' ends of the genomes, and (iii) two with one E/DLS at the 5' end of the genome and one at the 3' end of the genome. We found that moving the E/DLS to the 3' end of the genome resulted in at most an approximately factor of 5 reduction in virus titer in a single cycle of retroviral replication. Furthermore, we found no changes that were attributable to the alteration of the position of the E/DLS in the minus-strand DNA primer transfers or the plus-strand DNA primer transfers, the rate of homologous recombination, or the number of internal template switches in recombinant proviruses. These results indicate that any alignment or conformation necessary for retroviral replication or recombination is not the result of the position of the E/DLS.     

The HIV-1(Lai) RNA dimerization. Thermodynamic parameters associated with the transition from the kissing complex to the extended dimer.

Retroviruses contain dimeric RNA consisting of two identical copies of the genomic RNA. The interaction between these two RNA molecules occurs near their 5' ends. A region upstream from the splice donor comprising an auto-complementary sequence has been identified as being responsible for the initiation of the formation of dimeric HIV-1(Lai) RNA. This region (SL1), part of the PSI encapsidation domain, can adopt a stem-loop structure. It has already been shown that this stem-loop structure can initiate the formation of two distinct dimers differing in their thermostability: a loop-loop dimer or 'kissing complex' and an extended dimer. We report here a study using UV and 1D NMR spectroscopy of the dimerization of a short oligoribonucleotide (23 nucleotides) spanning nucleotides 248-270 of the HIV-1(Lai) SL1 sequence, in order to derive the thermodynamic parameters associated with the transition from the loop-loop complex to the extended dimer. The temperature dependence of the UV absorbency shows an hypochromicity for this transition with a small enthalpy change equal to - 29.4 +/- 5 kcal x mol-1, together with a concentration independent transition which implies a monomolecular reaction. On the other hand, our NMR results don't indicate a dissociation of the GCGCGC sequence engaged in the loop-loop interaction during the rearrangement of the loop-loop complex into the extended dimer. Our data suggest that the loop-loop interaction is maintained during the temperature dependent conformational change while the intramolecular base-pairing of the stems is disrupted and then reconstituted to form an intermolecular base-pairing leading to an extended dimer.     

Role of the 5' TAR stem--loop and the U5-AUG duplex in dimerization of HIV-1 genomic RNA

The HIV-1 genome consists of two identical RNAs that are linked together through noncovalent interactions involving nucleotides from the 5' untranslated region (5' UTR) of each RNA strand. The 5' UTR is the most conserved part of the HIV-1 RNA genome, and its 335 nucleotide residues form regulatory motifs that mediate multiple essential steps in the viral replication cycle. Here, studying the effect of selected mutations both singly and together with mutations disabling SL1 (SL1 is a 5' UTR stem-loop containing a palindrome called the dimerization initiation site), we have done a rather systematic survey of the 5' UTR requirements for full genomic RNA dimerization in grown-up (i.e., predominantly >/=10 h old) HIV-1 viruses produced by transfected human and simian cells. We have identified a role for the 5' transactivation response element (5' TAR) and a contribution of a long-distance base pairing between a sequence located at the beginning of the U5 region and nucleotides surrounding the AUG Gag initiation codon. The resulting intra- or intermolecular duplex is called the U5-AUG duplex. The other regions of the 5' UTR have been shown to play no systematic role in genomic RNA dimerization, except for a sequence located around the 3' end of a large stem-loop enclosing the primer binding site, and the well-documented SL1. Our data are consistent with a direct role for the 5' TAR in genomic RNA dimerization (possibly via a palindrome encompassing the apical loop of the 5' TAR).     

An analytical study of the dimerization of in vitro generated RNA of Moloney murine leukemia virus MoMuLV.

The genome of Moloney murine leukemia virus(MoMuLV) is composed of two identical RNA molecules joined at their 5' ends by the dimer linkage structure (DLS). Recently it was shown that in vitro generated MuLV RNA formed dimeric molecules and that dimerization sequences are located within the Psi encapsidation domain between positions 215 and 420. Conditions for the spontaneous dimerization of a MuLV RNA fragment encompassing the Psi domain have been investigated. The rate of spontaneous MuLV RNA dimer formation is dependent upon RNA, NaCl and MgCl2 concentrations as well as temperature. Thermal denaturation of in vitro generated dimer RNA of 350 nt, from positions 215 to 565, gave a Tm of about 58 degrees C in 100 mM NaCl. This Tm value is very close to that found for RNA corresponding to the 5' 755 nt and to the genomic 70 S RNA isolated from virions. According to thrermodynamic parameters derived from denaturation curves of MuLV dimer RNA generated in vitro, the dimer linkage structure probably involves short sequences.     

SL1 revisited: functional analysis of the structure and conformation of HIV-1 genome RNA

Background

The dimer initiation site/dimer linkage sequence (DIS/DLS) region of HIV is located on the 5′ end of the viral genome and suggested to form complex secondary/tertiary structures. Within this structure, stem-loop 1 (SL1) is believed to be most important and an essential key to dimerization, since the sequence and predicted secondary structure of SL1 are highly stable and conserved among various virus subtypes. In particular, a six-base palindromic sequence is always present at the hairpin loop of SL1 and the formation of kissing-loop structure at this position between the two strands of genomic RNA is suggested to trigger dimerization. Although the higher-order structure model of SL1 is well accepted and perhaps even undoubted lately, there could be stillroom for consideration to depict the functional SL1 structure while in vivo (in virion or cell).

Results

In this study, we performed several analyses to identify the nucleotides and/or basepairing within SL1 which are necessary for HIV-1 genome dimerization, encapsidation, recombination and infectivity. We unexpectedly found that some nucleotides that are believed to contribute the formation of the stem do not impact dimerization or infectivity. On the other hand, we found that one G–C basepair involved in stem formation may serve as an alternative dimer interactive site. We also report on our further investigation of the roles of the palindromic sequences on viral replication. Collectively, we aim to assemble a more-comprehensive functional map of SL1 on the HIV-1 viral life cycle.

Conclusion

We discovered several possibilities for a novel structure of SL1 in HIV-1 DLS. The newly proposed structure model suggested that the hairpin loop of SL1 appeared larger, and genome dimerization process might consist of more complicated mechanism than previously understood. Further investigations would be still required to fully understand the genome packaging and dimerization of HIV.

     

Role of the 5'-proximal stem-loop structure of the 5' untranslated region in replication and translation of hepatitis C virus RNA

Sequences of the untranslated regions at the 5' and 3' ends (5'UTR and 3'UTR) of the hepatitis C virus (HCV) RNA genome are highly conserved and contain cis-acting RNA elements for HCV RNA replication. The HCV 5'UTR consists of two distinct RNA elements, a short 5'-proximal stem-loop RNA element (nucleotides 1 to 43) and a longer element of internal ribosome entry site. To determine the sequence and structural requirements of the 5'-proximal stem-loop RNA element in HCV RNA replication and translation, a mutagenesis analysis was preformed by nucleotide deletions and substitutions. Effects of mutations in the 5'-proximal stem-loop RNA element on HCV RNA replication were determined by using a cell-based HCV replicon replication system. Deletion of the first 20 nucleotides from the 5' end resulted in elimination of cell colony formation. Likewise, disruption of the 5'-proximal stem-loop by nucleotide substitutions abolished the ability of HCV RNA to induce cell colony formation. However, restoration of the 5'-proximal stem-loop by compensatory mutations with different nucleotides rescued the ability of the subgenomic HCV RNA to replicate in Huh7 cells. In addition, deletion and nucleotide substitutions of the 5'-proximal stem-loop structure, including the restored stem-loop by compensatory mutations, all resulted in reduction of translation by two- to fivefold, suggesting that the 5'-proximal stem-loop RNA element also modulates HCV RNA translation. These findings demonstrate that the 5'-proximal stem-loop of the HCV RNA is a cis-acting RNA element that regulates HCV RNA replication and translation.     

Elements located upstream and downstream of the major splice donor site influence the ability of HIV-2 leader RNA to dimerize in vitro

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 termed stem-loop 1 (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 primer-binding site (PBS) and a stem-loop region 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 and 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-dependent tight dimers, probably by sequestering SL1 in a stable intramolecular arrangement. Moreover, we found that nucleotides downstream of SL1 decreased the rate of tight dimerization. Interestingly, dimerization at 37 degrees C in the presence of nucleocapsid protein increased the yield of SL1-mediated tight dimerization in vitro, even in the presence of the two interfering elements, suggesting a relationship between the nucleocapsid protein and activation of the SL1 dimerization signal in vivo.     

cis elements and trans-acting factors involved in dimer formation of murine leukemia virus RNA.

The genetic material of all retroviruses examined so far consists of two identical RNA molecules joined at their 5' ends by the dimer linkage structure (DLS). Since the precise location of the DLS as well as the mechanism and role(s) of RNA dimerization remain unclear, we analyzed the dimerization process of Moloney murine leukemia virus (MoMuLV) genomic RNA. For this purpose we derived an in vitro model for RNA dimerization. By using this model, murine leukemia virus RNA was shown to form dimeric molecules. Deletion mutagenesis in the 620-nucleotide leader of MoMuLV RNA showed that the dimer promoting sequences are located within the encapsidation element Psi between positions 215 and 420. Furthermore, hybridization assays in which DNA oligomers were used to probe monomer and dimer forms of MoMuLV RNA indicated that the DLS probably maps between positions 280 and 330 from the RNA 5' end. Also, retroviral nucleocapsid protein was shown to catalyze dimerization of MoMuLV RNA and to be tightly bound to genomic dimer RNA in virions. These results suggest that MoMuLV RNA dimerization and encapsidation are probably controlled by the same cis element, Psi, and trans-acting factor, nucleocapsid protein, and thus might be linked during virion formation.     

Moloney Murine Sarcoma Virus Genomic RNAs Dimerize via a Two-Step Process: a Concentration-Dependent Kissing-Loop Interaction Is Driven by Initial Contact between Consecutive Guanines

Retroviruses contain two plus-strand genomic RNAs, which are stably but noncovalently joined in their 5' regions by a dimer linkage structure (DLS). Two models have been put forward to explain the mechanisms by which the RNAs dimerize; each model emphasizes the role of specific molecular determinants. The kissing-loop model implicates interactions between palindromic sequences in the DLS region. The second model proposes that purine-rich stretches in the region form purine quartet structures. Here, we present an examination of the in vitro dimerization of Moloney murine sarcoma virus (MuSV) RNA in the context of these two models. Dimers were found to form spontaneously in a temperature-, time-, concentration-, and salt-dependent manner. In contrast to earlier reports, we found that deletion of neither the palindrome nor the consensus purine motifs (PuGGAPuA) affected the level of dimer formation at low concentrations of RNA. Rather, different purine-rich sequences, i.e., consecutive stretches of guanines, were found to enhance both in vitro RNA dimerization and in vivo viral replication. Biochemical evidence further suggests that these guanine-rich (G-rich) stretches form guanine quartet structures. We also found that the palindromic sequences could support dimerization at significantly higher RNA concentrations. In addition, the G-rich stretches were as important as the palindromic sequence for maintaining efficient viral replication. Overall, our data support a model that entails contributions from both of the previously proposed mechanisms of retroviral RNA dimerization.     

The 5' untranslated region of alfalfa mosaic virus RNA 1 is involved in negative-strand RNA synthesis

The three genomic RNAs of alfalfa mosaic virus each contain a unique 5' untranslated region (5' UTR). Replacement of the 5' UTR of RNA 1 by that of RNA 2 or 3 yielded infectious replicons. The sequence of a putative 5' stem-loop structure in RNA 1 was found to be required for negative-strand RNA synthesis. A similar putative 5' stem-loop structure is present in RNA 2 but not in RNA 3.     

A small and efficient dimerization/packaging signal of rat VL30 RNA and its use in murine leukemia virus-VL30-derived vectors for gene transfer.

Retroviral genomes consist of two identical RNA molecules associated at their 5' ends by the dimer linkage structure located in the packaging element (Psi or E) necessary for RNA dimerization in vitro and packaging in vivo. In murine leukemia virus (MLV)-derived vectors designed for gene transfer, the Psi + sequence of 600 nucleotides directs the packaging of recombinant RNAs into MLV virions produced by helper cells. By using in vitro RNA dimerization as a screening system, a sequence of rat VL30 RNA located next to the 5' end of the Harvey mouse sarcoma virus genome and as small as 67 nucleotides was found to form stable dimeric RNA. In addition, a purine-rich sequence located at the 5' end of this VL30 RNA seems to be critical for RNA dimerization. When this VL30 element was extended by 107 nucleotides at its 3' end and inserted into an MLV-derived vector lacking MLV Psi +, it directed the efficient encapsidation of recombinant RNAs into MLV virions. Because this VL30 packaging signal is smaller and more efficient in packaging recombinant RNAs than the MLV Psi + and does not contain gag or glyco-gag coding sequences, its use in MLV-derived vectors should render even more unlikely recombinations which could generate replication-competent viruses. Therefore, utilization of the rat VL30 packaging sequence should improve the biological safety of MLV vectors for human gene transfer.     

Dominant role of the 5' TAR bulge in dimerization of HIV-1 genomic RNA, but no evidence of TAR-TAR kissing during in vivo virus assembly

The 5' untranslated region of HIV-1 genomic RNA (gRNA) contains two stem-loop structures that appear to be equally important for gRNA dimerization: the 57-nucleotide 5' TAR, at the very 5' end, and the 35-nucleotide SL1 (nucleotides 243-277). SL1 is well-known for containing the dimerization initiation site (DIS) in its apical loop. The DIS is a six-nucleotide palindrome. Here, we investigated the mechanism of TAR-directed gRNA dimerization. We found that the trinucleotide bulge (UCU24) of the 5' TAR has dominant impacts on both formation of HIV-1 RNA dimers and maturation of the formed dimers. The ΔUCU trinucleotide deletion strongly inhibited the first process and blocked the other, thus impairing gRNA dimerization as severely as deletion of the entire 5' TAR, and more severely than deletion of the DIS, inactivation of the viral protease, or most severe mutations in the nucleocapsid protein. The apical loop of TAR contains a 10-nucleotide palindrome that has been postulated to stimulate gRNA dimerization by a TAR-TAR kissing mechanism analogous to the one used by SL1 to stimulate dimerization. Using mutations that strongly destabilize formation of the TAR palindrome duplex, as well as compensatory mutations that restore duplex formation to a wild-type-like level, we found no evidence of TAR-TAR kissing, even though mutations nullifying the kissing potential of the TAR palindrome could impair dimerization by a mechanism other than hindering of SL1. However, nullifying the kissing potential of TAR had much less severe effects than ΔUCU. By not uncovering a dimerization mechanism intrinsic to TAR, our data suggest that TAR mutations exert their effect 3' of TAR, yet not on SL1, because TAR and SL1 mutations have synergistic effects on gRNA dimerization.     

Structural requirements for nucleocapsid protein-mediated dimerization of avian leukosis virus RNA

The avian leukosis virus (ALV) belongs to the alpha group of retroviruses that are widespread in nature. The 5'-untranslated region of ALV genome contains the L3 element that is important for virus infectivity and the formation of an unstable RNA dimer in vitro. The L3 sequence is predicted to fold into a long stem-loop structure with two internal loops and an apical one. Phylogenetic analysis predicts that the L3 stem-loop is conserved in alpharetroviruses. Furthermore, a significant selection mechanism maintains a palindrome in the apical loop. The nucleocapsid protein of the alpharetroviruses (NCp12) is required for RNA dimer formation and replication in vivo. It is not known whether L3 can be an NCp12-mediated RNA dimerization site able to bind NCp12 with high affinity. Here, we report that NCp12 chaperones formation of a stable ALV RNA dimer through L3. To investigate the NCp12-mediated L3 dimerization reaction, we performed site-directed mutagenesis, gel retardation and heterodimerization assays and analysis of thermostability of dimeric RNAs. We show that the affinity of NCp12 for L3 is lower than its affinity for the microPsi RNA packaging signal. Results show that conservation of a long stem-loop structure and a loop-loop interaction are not required for NCp12-mediated L3 dimerization. We show that the L3 apical stem-loop is sufficient to form an extended duplex and the whole stem-loop L3 cannot be converted by NCp12 into a duplex extending throughout L3. Three-dimensional modelling of the stable L3 dimer supports the notion that the extended duplex may represent the minimal dimer linkage structure found in the genomic RNA.