On the stability of different experimental dimeric structures of the SL1 sequence from the genomic RNA of HIV-1 in solution: a molecular dynamics simulation and electrophoresis study.

SL1 is a stem-loop RNA sequence from the genome of HIV-1 thought to be the initiation site for the dimerization of the retroviral genomic RNA. The aim of this study is to check the stability in solution of different experimental dimeric structures available in the literature. Two kinds of dimer have been evidenced: an extended duplex looking like a double helix with two internal bulges and a kissing complex in which the monomers with a stem/loop conformation are linked by intermolecular loop-loop interactions. Two divergent experimental structures of the kissing complex from the Lai isolate are reported in the literature, one obtained from NMR (Mujeeb et al., Nature Structural Biology, 1998, Vol. 5, pp. 432-436) and the other one from x-ray crystallography (Ennifar et al., Nature Structural Biology, 2001, Vol. 8, pp. 1064-1068). A crystallographic structure of the Mal isolate was also reported (Ennifar et al., Nature Structure Biology, 2001, Vol. 8, pp. 1064-1068). Concerning the extended duplex, a NMR structure is available for Lai (Girard et al., Journal of Biomolecular Structure and Dynamics, 1999, Vol. 16, pp. 1145-1157) and a crystallographic structure for Mal (Ennifar et al., Structure, 1999, Vol. 7, pp. 1439-1449). Using a molecular dynamics technique, all these experimental structures have been simulated in solution with explicit water and counterions. We show that both extended duplex structures are stable. On the contrary, the crystallographic structures of the Lai and Mal kissing complexes are rapidly destabilized in aqueous environment. Finally, the NMR structure of the Lai loop-loop kissing complex remains globally stable over a 20 ns MD simulation, although large rearrangements occur at the level of the stem/loop junctions that are flexible, as shown from free energy calculations. These results are compared to electrophoresis experiments on dimer formation.

Modeling the dynamics of a mutated stem-loop in the SL1 domain of HIV-1Lai genomic RNA by 1H-NOESY spectra.

The cross-peaks of 1H-NOESY spectra at different time delays are compared to a mode-coupling diffusion (MCD) calculation, including the evaluation of the full 1H relaxation matrix, in the case of a 23 nucleotide fragment of the stem-loop SL1 domain of HIV-1Lai genomic RNA mutated in a single position. The MCD theory gives significant agreement with 1H relaxation experiments enabling a thorough understanding of the differential local dynamics along the sequence and particularly of the dynamics of nucleotides in the stem and in the loop. The differential dynamics of this hairpin structure is important in directing the dimerization of the retroviral genome, a fundamental step in the infectious process. The demonstration of a reliable use of time dependent NOE cross-peaks, largely available from NMR solution structure determination, coupled to MCD analysis, to probe the local dynamics of biological macromolecules, is a result of general interest of this paper.

Characterization of loose and tight dimer forms of avian leukosis virus RNA.

Retroviral genomes consist of two identical RNA molecules joined non-covalently near their 5'-ends. Recently, we showed that an imperfect autocomplementary sequence, located in the L3 domain, plays an essential role in avian sarcoma-leukosis virus (ASLV) RNA dimerization in vitro. This sequence can adopt a stem-loop structure and is involved in ASLV replication. Here, we found that in the absence of nucleocapsid protein, RNA transcripts of avian leukosis virus (ALV) were able to form two types of dimers in vitro that differ in their stability: a loose dimer, formed at a physiological temperature, and a tight dimer, formed at a high temperature. A mutational analysis was performed to define the features of these dimers. The results of this analysis unambiguously confirm that the two L3 stem-loops interact directly in both types of dimers. A loop-loop interaction is the main linkage in the loose dimer. In contrast, in the tight dimer, the stem and the loop of the L3 hairpin form an extended duplex. Surprisingly, we also found that the dimerization properties defined for our ALV strain (type SR-A) differ from those found in other ASLV strains.

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.

Dimer initiation sequence of HIV-1Lai genomic RNA: NMR solution structure of the extended duplex.

The genome of all retrovirus consists of two copies of genomic RNA which are noncovalently linked near their 5' end. A sequence localized immediately upstream from the splice donor site inside the HIV-1 psi-RNA region was identified as the domain responsible for the dimerization initiation. It was shown that a kissing complex and a stable dimer are both involved in the HIV-1Lai RNA dimerization process in vitro. The NCp7 protein activates the dimerization by converting a transient loop-loop complex into a more stable dimer. The structure of this transitory loop-loop complex was recently elucidated by Mujeeb et al. In work presented here, we use NMR spectroscopy to determine the stable extended dimer structure formed from a 23 nucleotides RNA fragment, part of the 35 nucleotides SL1 sequence. By heating to 90 degrees C, then slowly cooling this sequence, we were able to show that an extended dimer is formed. We present evidence for the three dimensional structure of this dimer. NMR data yields evidence for a zipper like motif A8A9.A16 existence. This motif enables the surrounding bases to be positioned more closely and permit the G7 and C17 bases to be paired. This is different to other related sequences where only the kissing complex is observed, we suggest that the zipper like motif AA.A could be an important stabilization factor of the extended duplex.

The annealing of tRNA3Lys to human immunodeficiency virus type 1 primer binding site is critically dependent on the NCp7 zinc fingers structure.

The nucleocapsid protein NCp7 of the human immunodeficiency virus type 1 contains two zinc fingers of the CX2CX4HX4C type, flanked by several basic residues, and plays a major role in viral infectivity. Thus, NCp7 was shown to promote annealing of the tRNA3Lys to the primer binding site, a key step in reverse transcription. However, previous in vitro experiments were unable to clarify the role of the zinc fingers in this process, due to nucleic acid aggregation induced by the basic N- and C-terminal domains of NCp7. We show here that deletion of these sequences in (12-53)NCp7 strongly reduces the formation of aggregates and allows a direct visualization of the binary or ternary complexes between NCp7 and nucleic acids by gel electrophoresis. (12-53)NCp7 is able to induce hybridization of the 33P tRNA3Lys and the human immunodeficiency virus type 1 viral RNA-(77-257), which contains the primer binding site. Modification of the proximal zinc finger conformation in Cys23(12-53)NCp7 led to a large reduction in this hybridization process, while replacement of Trp37 by Leu in the distal zinc fingers resulted in a complete absence of annealing activity. These data account for the in vivo loss of viral infectivity following these mutations and emphasize the critical role of the structure of the zinc finger domain of NCp7. This could facilitate a rational approach to new antiviral agents directed toward NCp7.

A short autocomplementary sequence plays an essential role in avian sarcoma-leukosis virus RNA dimerization.

Retroviral genomes consist of two identical RNA molecules joined noncovalently near their 5'-ends. Recently, two models have been proposed for RNA dimer formation on the basis of results obtained in vitro with human immunodeficiency virus type 1 RNA and Moloney murine leukemia virus RNA. It was first proposed that viral RNA dimerizes by forming an interstrand quadruple helix with purine tetrads. The second model postulates that RNA dimerization is initiated by a loop-loop interaction between the two RNA molecules. In order to better characterize the dimerization process of retroviral genomic RNA, we analyzed the in vitro dimerization of avian sarcoma-leukosis virus (ASLV) RNA using different transcripts. We determined the requirements for heterodimer formation, the thermal dissociation of RNA dimers, and the influence of antisense DNA oligonucleotides on dimer formation. Our results strongly suggest that purine tetrads are not involved in dimer formation. Data show that an autocomplementary sequence located upstream from the splice donor site and within a major packaging signal plays a crucial role in ASLV RNA dimer formation in vitro. This sequence is able to form a stem-loop structure, and phylogenetic analysis reveals that it is conserved in 28 different avian sarcoma and leukosis viruses. These results suggest that dimerization of ASLV RNA is initiated by a loop-loop interaction between two RNA molecules and provide an additional argument for the ubiquity of the dimerization process via loop-loop interaction.

NCp7 activates HIV-1Lai RNA dimerization by converting a transient loop-loop complex into a stable dimer.

Nucleocapsid protein 7 (NCp7), the human immunodeficiency virus type 1 (HIV-1) nucleocapsid protein, was shown to strongly potentiate the dimerization of the retroviral genomic RNA. This process involves the interaction of two retroviral RNA monomer subunits near their 5'-ends. A region located upstream from the splice donor site was recently identified as being responsible for the formation of dimeric HIV-1 RNA. This region appeared to be confined within a stem-loop structure, with an autocomplementary sequence in the loop. In an in vitro study of spontaneous dimer formation, we reported that the 77-402 RNA transcript forms two distinct dimers differing in their thermostability: D37 and D55. We identified D37 as a "kissing" complex structure, formed via a loop-loop interaction between the two monomers, and D55 as a double stranded structure involving all nucleotides of the stem-loop via canonical base pairing. In this report, we have characterized the role of NCp7 in the HIV-1Lai RNA dimerization process by using in vitro dimerization assays with RNA transcripts of different lengths and dimer thermal dissociation. Our results show that the nucleocapsid protein NCp7 activates RNA dimerization very likely through interaction with the kissing complex and converts it into a stable dimer. Furthermore, this NCp7-promoted conversion only occurs if the 240-280 stem-loop structure is present in HIV-1Lai RNA molecules and contains the autocomplementary G257CGCGC262 sequence. This study suggests that, under physiological conditions, an NCp7-mediated RNA conformational change is involved in the maturation of the HIV-1 RNA dimer.

A model of PSI dimerization: destabilization of the C278-G303 stem-loop by the nucleocapsid protein (NCp10) of MoMuLV.

We have shown that at low ionic strength (i.e., 100 mM NaCl) a short autocomplementary sequence spanning nucleotides C283 to G298 of MoMuLV RNA genome is involved in the process of PSI dimerization in vitro [Girard, P.-M., Bonnet-Mathonière, B., Muriaux, D., & Paoletti, J. (1995) Biochemistry 34, 9785-9794]. In order to identify other contributions of the PSI structure to RNA dimerization, we studied the kinetics of dimerization as a function of salt concentration of short RNA transcripts comprising or not the autocomplementary sequence C283-G298. We propose that, apart from the crucial role of this sequence in RNA dimerization, the 364-565 domain of PSI can interfere, in vitro, with the initiation of dimer formation. Intermolecular loop-loop recognitions involving the 364-565 domain could stabilize, in a salt concentration-dependent manner, a transient RNA dimer built around the loop-loop U288-A293 interaction. This dimer evolves toward a more stable structure which mainly corresponds to the annealing of two C283-G298 sequences. We also show that chemically synthesized NCp10 does not modify these steps but rather helps the system to pass over the energy barriers associated with the transition to stable RNA structures comprising the stem-loop C278-G303. Data obtained in the presence of NCp10 suggest a binding site size of 9 +/- 1 nucleotides per protein at 37 degrees C and a 10-20-fold increase in the rate constant (i.e., k1 = 24 000 +/- 7000 M-1 s-1) of dimer formation.

Nucleocapsid protein 10 activates dimerization of the RNA of Moloney murine leukaemia virus in vitro.

Short RNA species that encompass the psi domain of the retroviral genome spontaneously form dimers in vitro, and the retroviral nucleocapsid protein activates this dimerization in vitro. Addition of gag RNA sequences downstream of the 3' end of the psi domain decreases the level of spontaneous dimerization. Here, we report the effects of RNA length on dimerization in vitro, studied with RNA fragments from Moloney murine leukaemia virus that contain the psi domain and all or part of the gag sequence. Extension of the RNA leads to progressive inhibition of the in vitro dimerization process. Sequences located downstream of the 3' end of the psi domain seem to stabilize the monomeric structures. This stabilization participates in dimerization of the RNA sequences involved in the recognition of two RNA molecules. We studied the ability of nucleocapsid protein 10 to promote dimerization of such long RNA fragments, and found that the protein greatly enhances their dimerization in vitro. We propose that nucleocapsid protein 10 stimulates the overall dimerization process by reduction of the energy barrier that must be overcome to allow dimer formation. Our results show that dimerization of RNA form Moloney murine leukaemia virus in vitro is enhanced by nucleocapsid protein 10. This finding is in agreement with the involvement of the nucleocapsid protein in RNA dimerization in vivo.

A kissing complex together with a stable dimer is involved in the HIV-1Lai RNA dimerization process in vitro.

Retroviruses contain a dimeric RNA consisting of two identical molecules of genomic RNA. The interaction between the two monomers is thought to occur near their 5'ends. We previously identified a region upstream from the splice donor site, comprising an autocomplementary sequence, responsible for the formation of dimeric HIV-1Lai RNA [Muriaux, D., Girard, P.-M., Bonnet-Mathonire, B., & Paoletti, J.(1995) J. Biol. Chem. 270,8209-8216]. This region appeared to be confined within a putative stem-loop structure. Here we report an in vitro model under conditions of low inioc strength. Two dimers of RNA 77-402 were identified as a function of temperature, and a significant difference was found in their thermostability. Dimer D55, formed at 55 degrees Celsius, is more stable than dimer D37, formed at 37 degrees C. RNase probing experiments confirm the involvement of a stem-loop structure in the dimerization process. In the monomer, the free G257-CGCGC262 sequence forms a loop in the 240-280 region of RNA 77-402, whereas this sequence is engaged in base pairing when D55 and D37 dimers are formed. Our results show that the loop-loop interaction of the autocomplementary G257CGCGC262 sequence, though hydrogen bonding, is responsible for the formation of dimer D37 and strongly suggest that D37 is a "kissing" complex. In contrast, in dimer D55, all the nucleotides of the two hairpin stems, 243-254/264-277, are involved in a complete interstrand interaction.

A short autocomplementary sequence in the 5' leader region is responsible for dimerization of MoMuLV genomic RNA.

Previous work has shown that a region of Moloney murine leukemia virus (MoMuLV) RNA located between nucleotides 280 and 330 in the PSI region (nt 215-565) is implicated in the dimerization process. We show with a deletion from nucleotides 290-299 in PSI RNA transcripts and through an antisense oligonucleotide complementary to nucleotides 275-291 that the 283-298 region is involved in RNA dimer formation in vitro. In an attempt to further characterize the mechanism of dimer formation, a series of short RNA transcripts was synthesized which overlapps the PSI region of MoMuLV RNA. The dimerization of these RNAs is temperature dependent. The predicted secondary structure of the 278-303 region, as a function of temperature, reveals that this sequence is able to adopt two conformations: (1) the U288 AGCUA293 sequence in a loop; (2) part of the same nucleotides implicated in a stem. These results, together with thermodynamic analysis, strongly suggest that (1) the loop conformation of the UAGCUA sequence modulates the relative amount of RNA dimer and (2) a 16 bp long Watson-Crick base pairing is involved in RNA dimer formation. We propose that loop-loop recognition via the U288 AGCUA293 sequence leads to a stable structure induced by a stem-loop opening. Furthermore, our results do not support purine quartet formation as necessary for the dimerization of the 5' leader MoMuLV RNA.

An unusually stable purine(purine-pyrimidine) short triplex. The third strand stabilizes double-stranded DNA.

Classical models for DNA triple helix formation assume the stabilization of these structures through the formation of Hoogsteen hydrogen bonds. This assumes that G-rich duplex DNA is more stable than triplex DNA. We report the results of co-migration assay, dimethyl sulfate footprint, and UV spectroscopic melting studies that reveal that at least in some cases of short (13-mer) purine(purine-pyrimidine) triplex the stability of double-stranded DNA is increased by the binding of the third strand. Under conditions which are usually considered as physiological (10 mM MgCl2, 150 mM Na+ or K+) and with a rate of heating/cooling of 1 degrees C/min, there is a good reversibility of the melting profiles which is consistent with a high rate of triplex formation. Other factors than Hoogsteen hydrogen bonds should therefore be involved in triplex stabilization. We suggest that oligonucleotides with similar properties could be efficient agents for artificial gene regulation.

Dimerization of HIV-1Lai RNA at low ionic strength. An autocomplementary sequence in the 5' leader region is evidenced by an antisense oligonucleotide.

Genomic human immunodeficiency virus type 1 (HIV-1) RNA consists of two identical RNA molecules joined noncovalently near their 5' ends in a region called the dimer linkage structure (DLS). Previous work has shown that the putative DLS is localized in a 113-nucleotide domain encompassing the 5' end of the gag gene. This region contains conserved purine tracks that are thought to mediate dimerization through purine quartets. However, recently, an HIV-1Mal RNA dimerization model was proposed as the HIV-1Mal RNA dimerization initiation site, involving another region upstream from the splice donor site and possibly confined within a stem-loop. In the present study, we have investigated the dimerization of HIV-1Lai RNA, using in vitro dimerization assays under conditions of low ionic strength, predictive RNA secondary structures determined by computer folding, and antisense DNA oligonucleotides in order to discriminate between these two models. Our results suggest that purine quartets are not involved in the dimer structure of HIV-1Lai RNA and have led to the identification of a region upstream from the splice donor site. This region, comprising an autocomplementary sequence in a possible stem-loop structure, is responsible for the formation of dimeric HIV-1Lai RNA.

Conformational analysis of the 5' leader and the gag initiation site of Mo-MuLV RNA and allosteric transitions induced by dimerization.

Dimerization of genomic RNA is a key step in the retroviral life cycle and has been postulated to be involved in the regulation of translation, encapsidation and reverse transcription. Here, we have derived a secondary structure model of nucleotides upstream from psi and of the gag initiation region of Mo-MuLV RNA in monomeric and dimeric forms, using chemical probing, sequence comparison and computer prediction. The 5' domain is extensively base-paired and interactions take place between U5 and 5' leader sequences. The U5-PBS subdomain can fold in two mutually exclusive conformations: a very stable and extended helical structure (E form) in which 17 of the 18 nucleotides of the PBS are paired, or an irregular three-branch structure (B form) in which 10 nucleotides of the PBS are paired. The dimeric RNA adopts the B conformation. The monomeric RNA can switch from the E to the B conformation by a thermal treatment. If the E to B transition is associated to dimerization, it may facilitate annealing of the primer tRNAPro to the PBS by lowering the free energy required for melting the PBS. Furthermore, dimerization induces allosteric rearrangements around the SD site and the gag initiation region.

Spontaneous dimerization of retroviral MoMuLV RNA.

The genome of the Moloney murine leukemia virus (MoMuLV) is composed of two identical RNA molecules joined at their 5' ends by the dimer linkage structure (DLS). Dimerization sequences are located within the PSI encapsidation domain. We present here an overview of the work we have performed on spontaneous dimerization of a MoMuLV RNA fragment encompassing the PSI domain in order to understand the mechanism by which retroviral RNA dimerization takes place. We present kinetical, thermodynamical and conformational evidence which leads to the conclusion that the PSI domain is a structurally independent domain and that conformational changes are triggered by the dimerization process. We conclude that at least one particular region (nucleotides 278-309) of the RNA is directly involved in the process while the conformation of some other regions is changed probably because of a long-range effect.