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

RNA Structural Requirements for Nucleocapsid Protein-Mediated Extended Dimer Formation

Retroviruses package two copies of their genomic RNA (gRNA) as non-covalently linked dimers. Many studies suggest that the retroviral nucleocapsid protein (NC) plays an important role in gRNA dimerization. The upper part of the L3 RNA stem-loop in the 5' leader of the avian leukosis virus (ALV) is converted to the extended dimer by ALV NC. The L3 hairpin contains three stems and two internal loops. To investigate the roles of internal loops and stems in the NC-mediated extended dimer formation, we performed site-directed mutagenesis, gel electrophoresis, and analysis of thermostability of dimeric RNAs. We showed that the internal loops are necessary for efficient extended dimer formation. Destabilization of the lower stem of L3 is necessary for RNA dimerization, although it is not involved in the linkage structure of the extended dimer. We found that NCs from ALV, human immunodeficiency virus type 1 (HIV-1), and Moloney murine leukemia virus (M-MuLV) cannot promote the formation of the extended dimer when the apical stem contains ten consecutive base pairs. Five base pairs correspond to the maximum length for efficient L3 dimerization induced by the three NCs. L3 dimerization was less efficient with M-MuLV NC than with ALV NC and HIV-1 NC.

Visualizing Rous Sarcoma Virus Genomic RNA Dimerization in the Nucleus, Cytoplasm, and at the Plasma Membrane

Retroviruses are unique in that they package their RNA genomes as non-covalently linked dimers. Failure to dimerize their genomes results in decreased infectivity and reduced packaging of genomic RNA into virus particles. Two models of retrovirus genome dimerization have been characterized: in murine leukemia virus (MLV), genomic RNA dimerization occurs co-transcriptionally in the nucleus, resulting in the preferential formation of genome homodimers; whereas in human immunodeficiency virus (HIV-1), genomic RNA dimerization occurs in the cytoplasm and at the plasma membrane, with a random distribution of heterodimers and homodimers. Although in vitro studies have identified the genomic RNA sequences that facilitate dimerization in Rous sarcoma virus (RSV), in vivo characterization of the location and preferences of genome dimerization has not been performed. In this study, we utilized three single molecule RNA imaging approaches to visualize genome dimers of RSV in cultured quail fibroblasts. The formation of genomic RNA heterodimers within cells was dependent on the presence of the dimerization initiation site (DIS) sequence in the L3 stem. Subcellular localization analysis revealed that heterodimers were present the nucleus, cytoplasm, and at the plasma membrane, indicating that genome dimers can form in the nucleus. Furthermore, single virion analysis revealed that RSV preferentially packages genome homodimers into virus particles. Therefore, the mechanism of RSV genomic RNA dimer formation appears more similar to MLV than HIV-1.

NMR Studies of Retroviral Genome Packaging

Nearly all retroviruses selectively package two copies of their unspliced RNA genomes from a cellular milieu that contains a substantial excess of non-viral and spliced viral RNAs. Over the past four decades, combinations of genetic experiments, phylogenetic analyses, nucleotide accessibility mapping, in silico RNA structure predictions, and biophysical experiments were employed to understand how retroviral genomes are selected for packaging. Genetic studies provided early clues regarding the protein and RNA elements required for packaging, and nucleotide accessibility mapping experiments provided insights into the secondary structures of functionally important elements in the genome. Three-dimensional structural determinants of packaging were primarily derived by nuclear magnetic resonance (NMR) spectroscopy. A key advantage of NMR, relative to other methods for determining biomolecular structure (such as X-ray crystallography), is that it is well suited for studies of conformationally dynamic and heterogeneous systems—a hallmark of the retrovirus packaging machinery. Here, we review advances in understanding of the structures, dynamics, and interactions of the proteins and RNA elements involved in retroviral genome selection and packaging that are facilitated by NMR.

Rous Sarcoma Virus Genomic RNA Dimerization Capability In Vitro Is Not a Prerequisite for Viral Infectivity

Retroviruses package their full-length, dimeric genomic RNA (gRNA) via specific interactions between the Gag polyprotein and a “Ψ” packaging signal located in the gRNA 5′-UTR. Rous sarcoma virus (RSV) gRNA has a contiguous, well-defined Ψ element, that directs the packaging of heterologous RNAs efficiently. The simplicity of RSV Ψ makes it an informative model to examine the mechanism of retroviral gRNA packaging, which is incompletely understood. Little is known about the structure of dimerization initiation sites or specific Gag interaction sites of RSV gRNA. Using selective 2′-hydroxyl acylation analyzed by primer extension (SHAPE), we probed the secondary structure of the entire RSV 5′-leader RNA for the first time. We identified a putative bipartite dimerization initiation signal (DIS), and mutation of both sites was required to significantly reduce dimerization in vitro. These mutations failed to reduce viral replication, suggesting that in vitro dimerization results do not strictly correlate with in vivo infectivity, possibly due to additional RNA interactions that maintain the dimers in cells. UV crosslinking-coupled SHAPE (XL-SHAPE) was next used to determine Gag-induced RNA conformational changes, revealing G218 as a critical Gag contact site. Overall, our results suggest that disruption of either of the DIS sequences does not reduce virus replication and reveal specific sites of Gag–RNA interactions.

Retroviral RNA Dimerization: From Structure to Functions

The genome of the retroviruses is a dimer composed by two homologous copies of genomic RNA (gRNA) molecules of positive polarity. The dimerization process allows two gRNA molecules to be non-covalently linked together through intermolecular base-pairing. This step is critical for the viral life cycle and is highly conserved among retroviruses with the exception of spumaretroviruses. Furthermore, packaging of two gRNA copies into viral particles presents an important evolutionary advantage for immune system evasion and drug resistance. Recent studies reported RNA switches models regulating not only gRNA dimerization, but also translation and packaging, and a spatio-temporal characterization of viral gRNA dimerization within cells are now at hand. This review summarizes our current understanding on the structural features of the dimerization signals for a variety of retroviruses (HIVs, MLV, RSV, BLV, MMTV, MPMV…), the mechanisms of RNA dimer formation and functional implications in the retroviral cycle.

The basal translation rate of authentic HIV-1 RNA is regulated by 5'UTR nt-pairings at junction of R and U5

The paradigm protein synthesis rate is regulated by structural complexity of the 5′untranslated region (UTR) derives from bacterial and other riboswitches. In-solution, HIV-1 5′UTR forms two interchangeable long-range nucleotide (nt) -pairings, one sequesters the gag start codon promoting dimerization while the other sequesters the dimer initiation signal preventing dimerization. While the effect of these nt-pairings on dimerization and packaging has been documented their effect on authentic HIV translation in cellulo has remained elusive until now. HIV^NL4-3 5′UTR substitutions were designed to individually stabilize the dimer-prone or monomer-prone conformations, validated in-solution, and introduced to molecular clones. The effect of 5′UTR conformation on ribosome loading to HIV unspliced RNA and rate of Gag polypeptide synthesis was quantified in cellulo. Monomer- and dimer-prone 5′UTRs displayed equivalent, basal rate of translation. Gain-of-function substitution U103, in conjunction with previously defined nt-pairings that reorient AUG to flexible nt-pairing, significantly activated the translation rate, indicating the basal translation rate is under positive selection. The observed translation up-mutation focuses attention to nt-pairings at the junction of R and U5, a poorly characterized structure upstream of the characterized HIV riboswitch and demonstrates the basal translation rate of authentic HIV RNA is regulated independently of monomer:dimer equilibrium of the 5′UTR.

Analysis of cis-regulatory elements in the 5' untranslated region of murine leukemia virus controlling protein expression

It has previously been reported by us that high-level expression of the Env protein of Fr-MLV clone A8 in brains is crucial for induction of spongiform neurodegeneration, and that the 0.3-kb fragment containing the R, U5, and the 5' leader sequence of A8 is responsible for neuropathogenicity. In the present study, the role of the 5' untranslated region in protein expression was investigated. Luciferase expression vectors containing the LTR (R-U3-U5) and 5' leader sequence of A8 and non-neuropathogenic 57 Fr-MLV, designated gl-A8 and gl-57, and their chimeric vectors, were constructed, and transfected into rat glial cells F10. Replacement of the region containing the 3' half of R, U5, and 5' leader sequence of gl-A8 with that of 57 showed a reduction in luciferase activities, and replacement of this region of gl-57 with that of A8 showed increased luciferase activity. These results show that the region containing the 3' half of R, U5, and 5' leader sequence of A8 more efficiently up-regulates protein expression than 57. In particular, the 3' half of 5' leader of A8 was most responsible for the up-regulation of protein expression. Of interest, after replacement of the fragments between A8 and 57, changes in the activities of vectors containing A8-U3 paralleled the amount of mRNA, but the activities of vectors containing 57-U3 did not. Furthermore, it is suggested that the region containing R, U5, and the 5' leader sequence influences transcriptional or post-transcriptional steps, depending on the upstream sequence containing enhancer elements and promoter.

Nucleocapsid protein function in early infection processes

The role of nucleocapsid protein (NC) in the early steps of retroviral replication appears largely that of a facilitator for reverse transcription and integration. Using a wide variety of cell-free assay systems, the properties of mature NC proteins (e.g. HIV-1 p7(NC) or MLV p10(NC)) as nucleic acid chaperones have been extensively investigated. The effect of NC on tRNA annealing, reverse transcription initiation, minus-strand-transfer, processivity of reverse transcription, plus-strand-transfer, strand-displacement synthesis, 3' processing of viral DNA by integrase, and integrase-mediated strand-transfer has been determined by a large number of laboratories. Interestingly, these reactions can all be accomplished to varying degrees in the absence of NC; some are facilitated by both viral and non-viral proteins and peptides that may or may not be involved in vivo. What is one to conclude from the observation that NC is not strictly required for these necessary reactions to occur? NC likely enhances the efficiency of each of these steps, thereby vastly improving the productivity of infection. In other words, one of the major roles of NC is to enhance the effectiveness of early infection, thereby increasing the probability of productive replication and ultimately of retrovirus survival.

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.

Translational control of retroviruses

All replication-competent retroviruses contain three main reading frames, gag, pol and env, which are used for the synthesis of structural proteins, enzymes and envelope proteins respectively. Complex retroviruses, such as lentiviruses, also code for regulatory and accessory proteins that have essential roles in viral replication. The concerted expression of these genes ensures the efficient polypeptide production required for the assembly and release of new infectious progeny virions. Retroviral protein synthesis takes place in the cytoplasm and depends exclusively on the translational machinery of the host infected cell. Therefore, not surprisingly, retroviruses have developed RNA structures and strategies to promote robust and efficient expression of viral proteins in a competitive cellular environment.

[Analysis on primate lentivirus genome dimerization in virion]

The genomic RNA of retrovirus, including the primate lentivirus such as HIV, always form dimers in matured virions. It is likely that the presence of two genomes in one virion is advantageous for survival, providing an extra template that can be used when one RNA molecule is damaged, and/or giving genetic variety to their progeny. However, these ideas might not fully explain why the virion have to carry multiple identical RNAs in spite of the severe limitation of the space. We developed and utilized a novel system to investigate viral RNA dimerization in virion clearly and simply without affecting RNA packaging. The results of precise mapping of dimerization functional region strongly suggested that the RNA dimerization is one of the essential steps of RNA packaging.

How retroviruses select their genomes

As retroviruses assemble in infected cells, two copies of their full-length, unspliced RNA genomes are selected for packaging from a cellular milieu that contains a substantial excess of non-viral and spliced viral RNAs. Understanding the molecular details of genome packaging is important for the development of new antiviral strategies and to enhance the efficacy of retroviral vectors used in human gene therapy. Recent studies of viral RNA structure in vitro and in vivo and high-resolution studies of RNA fragments and protein-RNA complexes are helping to unravel the mechanism of genome packaging and providing the first glimpses of the initial stages of retrovirus assembly.

Preliminary physical mapping of RNA-RNA linkages in the genomic RNA of Moloney murine leukemia virus

Retrovirus particles contain two copies of their genomic RNA, held together in a dimer by linkages which presumably consist of a limited number of base pairs. In an effort to localize these linkages, we digested deproteinized RNA from Moloney murine leukemia virus (MLV) particles with RNase H in the presence of oligodeoxynucleotides complementary to specific sites in viral RNA. The cleaved RNAs were then characterized by nondenaturing gel electrophoresis. We found that fragments composed of nucleotides 1 to 754 were dimeric, with a linkage as thermostable as that between dimers of intact genomic RNA. In contrast, there was no stable linkage between fragments consisting of nucleotides 755 to 8332. Thus, the most stable linkage between monomers is on the 5' side of nucleotide 754. This conclusion is in agreement with earlier electron microscopic analyses of partially denatured viral RNAs and with our study (C. S. Hibbert, J. Mirro, and A. Rein, J. Virol. 78:10927-10938, 2004) of encapsidated nonviral mRNAs containing inserts of viral sequence. We obtained similar results with RNAs from immature MLV particles, in which the dimeric linkage is different from that in mature particles and has not previously been localized. The 5' and 3' fragments of cleaved RNA are all held together by thermolabile linkages, indicating the presence of tethering interactions between bases 5' and bases 3' of the cleavage site. When RNAs from mature particles were cleaved at nucleotide 1201, we detected tethering interactions spanning the cleavage site which are intramonomeric and are as strong as the most stable linkage between the monomers.

High affinity nucleocapsid protein binding to the muPsi RNA packaging signal of Rous sarcoma virus

The genomes of all retroviruses contain sequences near their 5' ends that interact with the nucleocapsid domains (NC) of assembling Gag proteins and direct their packaging into virus particles. Retroviral packaging signals often occur in non-contiguous segments spanning several hundred nucleotides of the RNA genome, confounding structural and mechanistic studies of genome packaging. Recently, a relatively short, 82 nucleotide region of the Rous sarcoma virus (RSV) genome, called muPsi, was shown to be sufficient to direct efficient packaging of heterologous RNAs into RSV-like particles. We have developed a method for the preparation and purification of large quantities of recombinant RSV NC protein, and have studied its interactions with native and mutant forms of the muPsi encapsidation element. NC does not bind with significant affinity to truncated forms of muPsi, consistent with earlier packaging and mutagenesis studies. Surprisingly, NC binds to the native muPsi RNA with affinity that is approximately 100 times greater than that observed for other previously characterized retroviral NC-RNA complexes (extrapolated dissociation constant K(d)=1.9 nM). Tight binding with 1:1 NC-muPsi stoichiometry is dependent on a conserved UGCG tetraloop in one of three predicted stem loops, and an AUG initiation codon controvertibly implicated in genome packaging and translational control. Loop nucleotides of other stem loops do not contribute to NC binding. Our findings indicate that the structural determinants of RSV genome recognition and NC-RNA binding differ considerably from those observed for other retroviruses.

Identification and characterization of critical cis-acting sequences within the yeast Ty1 retrotransposon

The yeast long terminal repeat (LTR) retrotransposon Ty1, like retroviruses, encodes a terminally redundant RNA, which is packaged into virus-like particles (VLPs) and is converted to a DNA copy by the process of reverse transcription. Mutations predicted to interfere with the priming events during reverse transcription and hence inhibit replication are known to dramatically decrease transposition of Ty1. However, additional cis-acting sequences responsible for Ty1 replication and RNA dimerization and packaging have remained elusive. Here we describe a modular mini-Ty1 element encoding the minimal sequence that can be retrotransposed by the Ty1 proteins, supplied in trans by a helper construct. Using a mutagenic screening strategy, we recovered transposition-deficient modular mini-Ty1-HIS3 elements with mutations in sequences required in cis for Ty1 replication and integration. Two distinct clusters of mutations mapped near the 5'-end of the Ty1 RNA. The clusters define a GAGGAGA sequence at the extreme 5'-end of the Ty1 transcript and a complementary downstream UCUCCUC sequence, 264 nt into the RNA. Disruption of the reverse complementarity of these two sequences decreased transposition and restoration of complementarity rescued transposition to wild-type levels. Ty1 cDNA was reduced in cells expressing RNAs with mutations in either of these short sequences, despite nearly normal levels of Ty1 RNA and VLPs. Our results suggest that the intramolecular interaction between the 5'-GAGGAGA and UCUCCUC sequences stabilizes an RNA structure required for efficient initiation of reverse transcription.

mRNA molecules containing murine leukemia virus packaging signals are encapsidated as dimers

Prior work by others has shown that insertion of psi (i.e., leader) sequences from the Moloney murine leukemia virus (MLV) genome into the 3' untranslated region of a nonviral mRNA leads to the specific encapsidation of this RNA in MLV particles. We now report that these RNAs are, like genomic RNAs, encapsidated as dimers. These dimers have the same thermostability as MLV genomic RNA dimers; like them, these dimers are more stable if isolated from mature virions than from immature virions. We characterized encapsidated mRNAs containing deletions or truncations of MLV psi or with psi sequences from MLV-related acute transforming viruses. The results indicate that the dimeric linkage in genomic RNA can be completely attributed to the psi region of the genome. While this conclusion agrees with earlier electron microscopic studies on mature MLV dimers, it is the first evidence as to the site of the linkage in immature dimers for any retrovirus. Since the Psi(+) mRNA is not encapsidated as well as genomic RNA, it is only present in a minority of virions. The fact that it is nevertheless dimeric argues strongly that two of these molecules are packaged into particles together. We also found that the kissing loop is unnecessary for this coencapsidation or for the stability of mature dimers but makes a major contribution to the stability of immature dimers. Our results are consistent with the hypothesis that the packaging signal involves a dimeric structure in which the RNAs are joined by intermolecular interactions between GACG loops.

Is HIV-1 RNA dimerization a prerequisite for packaging? Yes, no, probably?

During virus assembly, all retroviruses specifically encapsidate two copies of full-length viral genomic RNA in the form of a non-covalently linked RNA dimer. The absolute conservation of this unique genome structure within the Retroviridae family is strong evidence that a dimerized genome is of critical importance to the viral life cycle. An obvious hypothesis is that retroviruses have evolved to preferentially package two copies of genomic RNA, and that dimerization ensures the proper packaging specificity for such a genome. However, this implies that dimerization must be a prerequisite for genome encapsidation, a notion that has been debated for many years. In this article, we review retroviral RNA dimerization and packaging, highlighting the research that has attempted to dissect the intricate relationship between these two processes in the context of HIV-1, and discuss the therapeutic potential of these putative antiretroviral targets.

The human T-cell lymphotropic virus type-I dimerization initiation site forms a hairpin loop, unlike previously characterized retroviral dimerization motifs

The formation of genomic RNA dimers during the retroviral life cycle is essential for optimal viral replication and infectivity. The sequences and RNA structures responsible for this interaction are located in the untranslated 5' leader RNA, along with other cis-acting signals. Dimer formation occurs by specific interaction between identical structural motifs. It is believed that an initial kissing hairpin forms following self-recognition by autocomplementary RNA loops, leading to formation of an extended stable duplex. The dimerization initiation site (DIS) of the deltaretrovirus human T-cell lymphotropic virus type-I (HTLV-I) has been previously localized to a 14-nucleotide sequence predicted to contain an RNA stem loop. Biochemical probing of the monomeric RNA structure using RNAse T1, RNAse V1, RNAse U2, lead acetate, and dimethyl sulfate has led to the generation of the first structural map of the HTLV-I DIS. A comprehensive data set of individual nucleotide modifications reveals that the structural motif responsible for HTLV-I RNA dimerization forms a trinucleotide RNA loop, unlike any previously characterized retroviral dimerization motif. Molecular modeling demonstrates that this can be formed by an unusual C:synG base pair closing the loop. Comparative phylogeny indicates that such a motif may also exist in other deltaretroviruses.

The retroviral RNA dimer linkage: different structures may reflect different roles

Retroviruses are unique among virus families in having dimeric genomes. The RNA sequences and structures that link the two RNA molecules vary, and these differences provide clues as to the role of this feature in the viral lifecycles. This review draws upon examples from different retroviral families. Differences and similarities in both secondary and tertiary structure are discussed. The implication of varying roles for the dimer linkage in related viruses is considered.

The hepatitis C virus Core protein is a potent nucleic acid chaperone that directs dimerization of the viral (+) strand RNA in vitro

The hepatitis C virus (HCV) is an important human pathogen causing chronic hepatitis, liver cirrhosis and hepatocellular carcinoma. HCV is an enveloped virus with a positive-sense, single-stranded RNA genome encoding a single polyprotein that is processed to generate viral proteins. Several hundred molecules of the structural Core protein are thought to coat the genome in the viral particle, as do nucleocapsid (NC) protein molecules in Retroviruses, another class of enveloped viruses containing a positive-sense RNA genome. Retroviral NC proteins also possess nucleic acid chaperone properties that play critical roles in the structural remodelling of the genome during retrovirus replication. This analogy between HCV Core and retroviral NC proteins prompted us to investigate the putative nucleic acid chaperoning properties of the HCV Core protein. Here we report that Core protein chaperones the annealing of complementary DNA and RNA sequences and the formation of the most stable duplex by strand exchange. These results show that the HCV Core is a nucleic acid chaperone similar to retroviral NC proteins. We also find that the Core protein directs dimerization of HCV (+) RNA 3' untranslated region which is promoted by a conserved palindromic sequence possibly involved at several stages of virus replication.

NMR structure of the 101-nucleotide core encapsidation signal of the Moloney murine leukemia virus

The full length, positive-strand genome of the Moloney Murine Leukemia Virus contains a "core encapsidation signal" that is essential for efficient genome packaging during virus assembly. We have determined the structure of a 101-nucleotide RNA that contains this signal (called mPsi) using a novel isotope-edited NMR approach. The method is robust and should be generally applicable to larger RNAs. mPsi folds into three stem loops, two of which (SL-C and SL-D) co-stack to form an extended helix. The third stem loop (SL-B) is connected to SL-C by a flexible, four-nucleotide linker. The structure contains five mismatched base-pairs, an unusual C.CG base-triple platform, and a novel "A-minor K-turn," in which unpaired adenosine bases A340 and A341 of a GGAA bulge pack in the minor groove of a proximal stem, and a bulged distal uridine (U319) forms a hydrogen bond with the phosphodiester of A341. Phylogenetic analyses indicate that these essential structural elements are conserved among the murine C-type retroviruses.

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.

The leader of human immunodeficiency virus type 1 genomic RNA harbors an internal ribosome entry segment that is active during the G2/M phase of the cell cycle

The 5' leader of the human immunodeficiency virus type 1 (HIV-1) genomic RNA contains highly structured domains involved in key steps of the viral life cycle. These RNA domains inhibit cap-dependent protein synthesis. Here we report that the HIV-1 5' leader harbors an internal ribosome entry site (IRES) capable of driving protein synthesis during the G(2)/M cell cycle phase in which cap-dependent initiation is inhibited. The HIV-1 IRES was delineated with bicistronic mRNAs in in vitro and ex vivo assays. The HIV-1 leader IRES spans nucleotides 104 to 336 and partially overlaps the major determinants of genomic RNA packaging. These data strongly suggest that, as for HIV-1 transcription, IRES-mediated translation initiation could play an important role in virus replication during virus-induced G(2)/M cell cycle arrest.

Structure of the intact stem and bulge of HIV-1 Psi-RNA stem-loop SL1

The Psi-RNA packaging signal of the human immunodeficiency virus type-1 (HIV-1) genome contains a 35 nucleotide stem-loop, termed SL1, which is important for efficient genome packaging during virus assembly and for reverse transcription during infectivity. The predicted secondary structure of SL1 consists of an upper stem with a GC-rich loop that facilitates dimerization, a lower stem, and an intervening bulge (G5, A24-G25-G26) that is both strictly conserved and essential for efficient packaging of the viral genome. The structure of the upper stem in both the kissing and duplex dimer forms have been determined recently. Here, we report the structure of an engineered form of SL1 (SL1(m)) that contains a GAGA tetraloop substituted for the GC-rich loop. This construct does not aggregate and remains monomeric at concentrations up to 1mM, enabling structural studies of the intact stems and bulge. The structure was refined using 1H-13C residual dipolar couplings. The upper stem (C6-G12, C17-G23) is in close agreement with X-ray structures of kissing and duplex dimer forms of related oligoribonucleotides, and nucleotides C1-G4 and C27-G30 form the expected A-helical lower stem. Residues G5 and A24 of the predicted bulge form a G-A mismatch that stacks with the upper stem, and residues G25 and G26 stack between the G-A mismatch and the lower stem in a manner that produces a hole in the center of the bulge and a 25(+/-4) degrees bend between the upper and lower stems. SL1(m) exhibits relatively poor affinity for the HIV-1 nucleocapsid protein, suggesting that the bulge plays other roles in genome packaging.

RNA loop-loop interactions as dynamic functional motifs

RNA loop-loop interactions are frequently used to trigger initial recognition between two RNA molecules. In this review, we present selected well-documented cases that illustrate the diversity of biological processes using RNA loop-loop recognition properties. The first one is related to natural antisense RNAs that play a variety of regulatory functions in bacteria and their extra-chromosomal elements. The second one concerns the dimerization of HIV-1 genomic RNA, which is responsible for the encapsidation of a diploid RNA genome. The third one concerns RNA interactions involving double-loop interactions. These are used by the bicoid mRNA to form dimers, a property that appears to be important for mRNA localization in drosophila embryo, and by bacteriophage phi29 pRNA which forms hexamers that participate in the translocation of the DNA genome through the portal vertex of the capsid. Despite the high diversity of systems and mechanisms, some common features can be highlighted. (1) Efficient recognition requires rapid bi-molecular binding rates, regardless of the RNA pairing scheme. (2) The initial recognition is favored by particular conformations of the loops enabling a proper presentation of nucleotides (generally a restricted number) that initiate the recognition process. (3) The fate of the initial reversible loop-loop complex is dictated by both functional and structural constraints. RNA structures have evolved either to "freeze" the initial complex, or to convert it into a more stable one, which involves propagation of intermolecular interactions along topologically feasible pathways. Stabilization of the initial complex may also be assisted by proteins and/or formation of additional contacts.

Regulated HIV-2 RNA dimerization by means of alternative RNA conformations

The dimer initiation site (DIS) hairpin of the HIV-2 untranslated leader RNA mediates in vitro dimerization through 'loop-loop kissing' of a loop-exposed palindrome sequence. Premature RNA dimerization must be prevented during the retroviral life cycle. A regulatory mechanism has been proposed for the HIV-1 leader RNA that can adopt an alternative conformation in which the DIS motif is effectively masked by long-distance base pairing with upstream leader sequences. We now report that HIV-2 RNA dimerization is also regulated. Sequestering of the DIS motif by base pairing interactions with downstream leader sequences mediates a switch to a dimerization-impaired conformation. The existence of two alternative conformations of the HIV-2 leader RNA is supported by UV melting experiments. Furthermore, the equilibrium between the two conformations can be shifted by annealing of antisense oligonucleotides or by deletion of certain leader regions. These measures have a profound impact on the dimerization properties of the transcript, demonstrating a mutual exclusivity between the alternative conformation and dimerization, similar to what has been described for the HIV-1 leader. The overall resemblance in regulation of HIV-1 and HIV-2 RNA dimerization suggests that a similar mechanism may be operating in other lentiviruses and perhaps all retroviridae.

Alternate usage of two dimerization initiation sites in HIV-2 viral RNA in vitro

An essential step in the replication cycle of all retroviruses is the dimerization of genomic RNA prior to or during encapsidation and budding. In HIV-1, a stem-loop structure in the genomic RNA called the dimerization initiation site, or DIS, has been well characterized. However, the identification of the structure(s) necessary for dimerization of HIV-2 genomic RNA has been less straightforward, as reflected by recent conflicting reports. Here, using a variety of mutant and wild-type RNA constructs and a systematic analysis of experimental conditions, we demonstrate that two dimerization sites in HIV-2 RNA are clearly discernible under different experimental conditions. A short sequence overlapping the primer binding site acts as the default dimerization site for wild-type viral RNA transcripts of several lengths provided that dimerization incubation conditions do not include a high heat step (>50 degrees C), and electrophoresis is carried out under mild conditions that do not deplete the RNA of magnesium. However, some RNA constructs are able to dimerize through stem-loop 1 (SL1), which is the structure homologous to the HIV-1 DIS, under certain experimental conditions. Interestingly, deletion or mutation of the default PBS dimerization site leads to efficient usage of the SL1 dimerization site. This study defines conditions under which each site may be used for dimerization and demonstrates, furthermore, the facility with which the two sites can substitute for each other. This is suggestive of a switching mechanism that may be used in the viral replication cycle.

In vitro evidence that the untranslated leader of the HIV-1 genome is an RNA checkpoint that regulates multiple functions through conformational changes

The HIV-1 RNA genome forms dimers through base pairing of a palindromic 6-mer sequence that is exposed in the loop of the dimer initiation signal (DIS) hairpin structure (loop-loop kissing). The HIV-1 leader RNA can adopt a secondary structure conformation that is not able to dimerize because the DIS hairpin is not folded. Instead, this DIS motif is base-paired in a long distance interaction (LDI) that extends the stem of the primer-binding site domain. In this study, we show that targeting of the LDI by either antisense oligonucleotides or specific mutations can induce the conformational switch to a branched multiple hairpin (BMH) structure, and this LDI-to-BMH switch coincides with increased RNA dimerization. Another interesting finding is that the extended LDI stem can resist a certain level of destabilization, indicating that a buffer is created to prevent a premature conformational switch and early dimerization. Because the tRNA(Lys3) primer for reverse transcription anneals to multiple sequence elements of the HIV-1 leader RNA, including sequences in the LDI stem, we tested whether tRNA-annealing can destabilize the LDI stem such that RNA dimerization is triggered. Using a combination of stem-destabilizing approaches, we indeed measured a small but significant effect of tRNA-annealing on the ability of the RNA template to form dimers. This observation suggests that HIV-1 RNA can act as a checkpoint to control and coordinate different leader functions through conformational switches. This in vitro result should be verified in subsequent in vivo studies with HIV-infected cells.

A new peculiar DNA structure: NMR solution structure of a DNA kissing complex

The deoxyoligoribonucleotide d(CTTGCTGAAGCGCGCACGGCAAG) (dSL1) corresponding to the reverse transcripted sequence of the dimerization initiation site SL1 of HIV- 1(Lai) RNA was synthesized using phosphoramidite chemistry. Like its oligoribonucleotide counterpart, dSL1 dimerized spontaneously in solution. Here we report the first NMR solution structure of a kissing complex formed with two DNA strands. The melting point of the DNA dimer (35 degrees C) was found slightly higher than the one of the corresponding RNA dimer (32 degrees C). Despite this only slight difference in melting point, several structural differences were observed between the ribo- and the deoxyribo- dimers. The solution structure of the deoxy- dimer was a symmetric homodimer with a loop-loop interaction stabilized by four central G-C base-pairs, a head to tail A-A base-pair arrangement between the A8 residues of the two strands and a stacking of A9 with C15. As a consequence, G10 was not paired and occupied a position outside the stem and the loop. Each stem was formed by seven base-pairs whose axis made an angle of about 100 degree with the plane of the loops. The distortion of the helix at the junction of the stem and of the loop induced a fold up of the A8pA9 step with a phosphate-phosphate distance lowered to 4.5 A. The plane of the non-canonical A-A base-pair was oriented perpendicularly to the axis of the stems. The four central base-pairs formed an open fan-shaped motif with an angle of 20 degrees between the bases and each of them was oriented perpendicularly to the A8-A8 plane. The deviation of the computed chemical shifts and the experimental ones for the aromatic proton was always less than 0.25ppm for each of the 16 converged solution structures and their average less than 0.1ppm.

Identification of a high affinity nucleocapsid protein binding element within the Moloney murine leukemia virus Psi-RNA packaging signal: implications for genome recognition

Murine leukemia virus (MLV) is currently the most widely used gene delivery system in gene therapy trials. The simple retrovirus packages two copies of its RNA genome by a mechanism that involves interactions between the nucleocapsid (NC) domain of a virally-encoded Gag polyprotein and a segment of the RNA genome located just upstream of the Gag initiation codon, known as the Psi-site. Previous studies indicated that the MLV Psi-site contains three stem loops (SLB-SLD), and that stem loops SLC and SLD play prominent roles in packaging. We have developed a method for the preparation and purification of large quantities of recombinant Moloney MLV NC protein, and have studied its interactions with a series of oligoribonucleotides that contain one or more of the Psi-RNA stem loops. At RNA concentrations above approximately 0.3 mM, isolated stem loop SLB forms a duplex and stem loops SL-C and SL-D form kissing complexes, as expected from previous studies. However, neither the monomeric nor the dimeric forms of these isolated stem loops binds NC with significant affinity. Longer constructs containing two stem loops (SL-BC and SL-CD) also exhibit low affinities for NC. However, NC binds with high affinity and stoichiometrically to both the monomeric and dimeric forms of an RNA construct that contains all three stem loops (SL-BCD; K(d)=132(+/-55) nM). Titration of SL-BCD with NC also shifts monomer-dimer equilibrium toward the dimer. Mutagenesis experiments demonstrate that the conserved GACG tetraloops of stem loops C and D do not influence the monomer-dimer equilibrium of SL-BCD, that the tetraloop of stem loop B does not participate directly in NC binding, and that the tetraloops of stem loops C and D probably also do not bind to NC. These surprising results differ considerably from those observed for HIV-1, where NC binds to individual stem loops with high affinity via interactions with exposed residues of the tetraloops. The present results indicate that MLV NC binds to a pocket or surface that only exists in the presence of all three stem loops.

Oligonucleotide mapping of the core genomic RNA dimer linkage in human T-cell leukaemia virus type-1

We have previously mapped the sequences required for dimerisation of the 5' leader of the human T-cell leukaemia virus type-1 (HTLV-1) genome. The smallest sequence necessary and sufficient for dimer formation, in vitro, was ascertained to be a 37 nucleotide (nt) region downstream of the splice donor and just upstream of the primer binding site. Deletion of a 32 base-pair sequence encompassing this region within the provirus was associated with a minor decrease in infectivity of the virus in an in vitro system. To further map and help elucidate the nature of the dimer linkage, we used RNA and DNA oligonucleotide competition assays to define the nucleotides involved. These experiments revealed that a 14 nt sequence containing a potential stem loop structure, formed from a palindromic sequence, is important for dimer formation. This was confirmed by the ability of this RNA sequence to form heterodimers with larger RNA transcripts from the same region, while sequences lacking this motif could not. RNA transcripts containing the reverse sequence, the same nucleotides in a random arrangement, and complementary DNA oligos, all failed to form heterodimers with the 14 nt sequence. The primary dimer initiation site of HTLV-1 has thus been located to a 14 nt palindrome containing sequence, and dimerisation is shown to be dependent on specific sense-sense RNA interactions.

The kissing hairpin sequence promotes recombination within the HIV-I 5' leader region

The role of RNA-RNA template interactions in facilitating recombination during reverse transcription of minus strand DNA has been examined. The tested hypothesis is that template switching by reverse transcriptase is promoted at sites where homologous regions of two RNAs are brought in close proximity via stable intertemplate interactions. Frequency and distribution of template switching between homologous donor and acceptor RNAs were examined within the human immunodeficiency virus type I (HIV-I) 5'-untranslated region (UTR) containing the dimer initiation sequence (DIS). Results were compared with control nondimerizing templates from the pol region. The dimerizing UTR templates displayed a 4-fold higher transfer efficiency than the control. A striking 53% of transfers in the UTR mapped near the DIS, of which two-thirds occurred immediately 5' to this sequence. In the UTR template, deletion of the DIS hairpin disrupted template dimerization and caused a 4-fold drop in transfer efficiency. Insertion of the DIS within the pol template increased both dimerization and transfer efficiency. Transfer distributions revealed that in both sets of templates, DIS-induced dimerization increased the efficiency of transfers across the whole template, with the transfers peaking around the dimerization site. Overall, these results suggest that template dimerization facilitated by the unique geometry of the DIS-promoted kissing interactions effectively promotes recombination within the HIV-I 5'-UTR.

The dimer initiation site hairpin mediates dimerization of the human immunodeficiency virus, type 2 RNA genome

The untranslated leader of retroviral RNA genomes encodes multiple structural signals that are critical for virus replication. In the human immunodeficiency virus, type 1 (HIV-1) leader, a hairpin structure with a palindrome-containing loop is termed the dimer initiation site (DIS), because it triggers in vitro RNA dimerization through base pairing of the loop-exposed palindromes (kissing loops). Controversy remains regarding the region responsible for HIV-2 RNA dimerization. Different studies have suggested the involvement of the transactivation region, the primer binding site, and a hairpin structure that is the equivalent of the HIV-1 DIS hairpin. We have performed a detailed mutational analysis of the HIV-2 leader RNA, and we also used antisense oligonucleotides to probe the regions involved in dimerization. Our results unequivocally demonstrate that the DIS hairpin is the main determinant for HIV-2 RNA dimerization. The 6-mer palindrome sequence in the DIS loop is essential for dimer formation. Although the sequence can be replaced by other 6-mer palindromes, motifs that form more than two A/U base pairs do not dimerize efficiently. The inability to form stable kissing-loop complexes precludes formation of dimers with more extended base pairing. Structure probing of the DIS hairpin in the context of the complete HIV-2 leader RNA suggests a 5-base pair elongation of the DIS stem as it is proposed in current RNA secondary structure models. This structure is supported by phylogenetic analysis of leader RNA sequences from different viral isolates, indicating that RNA genome dimerization occurs by a similar mechanism for all members of the human and simian immunodeficiency viruses.

Palindromic sequence plays a critical role in human foamy virus dimerization

The retroviral RNA genome is dimeric, consisting of two identical strands of RNA linked near their 5' ends by a dimer linkage structure. Previously it was shown that human foamy virus (HFV) RNA transcribed in vitro contained three sites, designated SI, SII, and SIII, which contributed to the dimerization process (O. Erlwein, D. Cain, N. Fischer, A. Rethwilm, and M. O. McClure, Virology 229:251-258, 1997). To characterize these sites further, a series of mutants were designed and tested for their ability to dimerize in vitro. The primer binding site and a G tetrad in SI were dispensable for dimerization. However, a mutant that changed the 3' end of SI migrated slower on nondenaturing gels than wild-type RNA dimers. The sequence composition of the SII palindrome, consisting of 10 nucleotides, proved to be critical for in vitro dimerization, since mutations within this sequence or replacement of the sequence with a different palindrome of equal length impaired in vitro dimerization. The length of the palindrome also seems to play an important role. A moderate extension to 12 nucleotides was tolerated, whereas an extension to 16 nucleotides or more impaired dimerization. When nucleotides flanking the palindrome were mutated in a random fashion, dimerization was unaffected. Changing the SIII sequence also led to decreased dimer formation, confirming its contribution to the dimerization process. Interesting mutants were cloned into the infectious molecular clone of HFV, HSRV-2, and were transfected into BHK-21 cells. Mutations in SII that reduced dimerization in vitro also abolished virus replication. In contrast, constructs containing mutations in SI and SIII replicated to some extent in cell culture after an initial drop in viral replication. Analysis of the SIM1 mutant revealed reversion to the wild type but with the insertion of an additional two nucleotides. Analysis of cell-free virions demonstrated that both replication-competent and replication-defective mutants packaged nucleic acid. Thus, efficient dimerization is a critical step for HFV to generate infectious virus, but HFV RNA dimerization is not a prerequisite for packaging.

Duplication of the primary encapsidation and dimer linkage region of human immunodeficiency virus type 1 RNA results in the appearance of monomeric RNA in virions

The dimerization initiation site (DIS) and the dimer linkage sequences (DLS) of human immunodeficiency virus type 1 have been shown to mediate in vitro dimerization of genomic RNA. However, the precise role of the DIS-DLS region in virion assembly and RNA dimerization in virus particles has not been fully elucidated, since deletion or mutation of the DIS-DLS region also abolishes the packaging ability of genomic RNA. To characterize the DIS-DLS region without altering packaging ability, we generated mutant constructs carrying a duplication of approximately 1,000 bases including the encapsidation signal and DIS-DLS (E/DLS) region. We found that duplication of the E/DLS region resulted in the appearance of monomeric RNA in virus particles. No monomers were observed in virions of mutants carrying the E/DLS region only at ectopic positions. Monomers were not observed when pol or env regions were duplicated, indicating an absolute need for two intact E/DLS regions on the same RNA for generating particles with monomeric RNA. These monomeric RNAs were most likely generated by intramolecular interaction between two E/DLS regions on one genome. Moreover, incomplete genome dimerization did not affect RNA packaging and virion formation. Examination of intramolecular interaction between E/DLS regions could be a convenient tool for characterizing the E/DLS region in virion assembly and RNA dimerization within virus particles.

Rous sarcoma virus translation revisited: characterization of an internal ribosome entry segment in the 5' leader of the genomic RNA

The 5' leader of Rous sarcoma virus (RSV) genomic RNA and of retroviruses in general is long and contains stable secondary structures that are critical in the early and late steps of virus replication such as RNA dimerization and packaging and in the process of reverse transcription. The initiation of RSV Gag translation has been reported to be 5' cap dependent and controlled by three short open reading frames located in the 380-nucleotide leader upstream of the Gag start codon. Translation of RSV Gag would thus differ from that prevailing in other retroviruses such as murine leukemia virus, reticuloendotheliosis virus type A, and simian immunodeficiency virus, in which an internal ribosome entry segment (IRES) in the 5' end of the genomic RNA directs efficient Gag expression despite stable 5' secondary structures. This prompted us to investigate whether RSV Gag translation might be controlled by an IRES-dependent mechanism. The results show that the 5' leaders of RSV and v-Src RNA exhibit IRES properties, since these viral elements can promote efficient translation of monocistronic RNAs in conditions inhibiting 5' cap-dependent translation. When inserted between two cistrons in a canonical bicistronic construct, both the RSV and v-Src leaders promote expression of the 3' cistron. A genetic analysis of the RSV leader allowed the identification of two nonoverlapping 5' and 3' leader domains with IRES activity. In addition, the v-Src leader was found to contain unique 3' sequences promoting an efficient reinitiation of translation. Taken together, these data lead us to propose a new model for RSV translation.

Human immunodeficiency virus type 1 Vif protein is an integral component of an mRNP complex of viral RNA and could be involved in the viral RNA folding and packaging process

Virion infectivity factor (Vif) is a protein encoded by human immunodeficiency virus types 1 and 2 (HIV-1 and -2) and simian immunodeficiency virus, plus other lentiviruses, and is essential for viral replication either in vivo or in culture for nonpermissive cells such as peripheral blood lymphoid cells, macrophages, and H9 T cells. Defects in the vif gene affect virion morphology and reverse transcription but not the expression of viral components. It has been shown that Vif colocalizes with Gag in cells and Vif binds to the NCp7 domain of Gag in vitro. However, it seems that Vif is not specifically packaged into virions. The molecular mechanism(s) for Vif remains unknown. In this report, we demonstrate that HIV-1 Vif is an RNA-binding protein and specifically binds to HIV-1 genomic RNA in vitro. Further, Vif binds to HIV-1 RNA in the cytoplasm of virus-producing cells to form a 40S mRNP complex. Coimmunoprecipitation and in vivo UV cross-linking assays indicated that Vif directly interact with HIV-1 RNA in the virus-producing cells. Vif-RNA binding could be displaced by Gag-RNA binding, suggesting that Vif protein in the mRNP complex may mediate viral RNA interaction with HIV-1 Gag precursors. Furthermore, we have demonstrated that these Vif mutants that lose the RNA binding activity in vitro do not support vif-deficient HIV-1 replication in H9 T cells, suggesting that the RNA binding capacity of Vif is important for its function. Further studies regarding Vif-RNA interaction in virus-producing cells will be important for studying the function of Vif in the HIV-1 life cycle.

A retroviral RNA kissing complex containing only two G.C base pairs

The dimerization of viral RNA through noncovalent interactions at their 5' ends is a key step in the life cycle of retroviruses. In Moloney murine leukemia virus, three stem-loops are important in this process. One is a self-complementary tetraloop (H1), but the other two stem-loops (H2, H3) contain highly conserved GACG tetraloops that are not self-complementary sequences. Using two-dimensional NMR, we determined the structure of the H3 stem-loop. Surprisingly, it forms a stable, homodimeric kissing complex through only two intermolecular G small middle dotC base pairs. Cross-strand interactions of the adenines adjacent to the intermolecular G small middle dotC base pairs, plus unusual strong electrostatic interactions around the base pairs, contribute to the unexpected stability. This structure shows how even stem-loops without self-complementary sequences can facilitate the intermolecular recognition between two identical RNAs, and thus initiate dimerization and encapsidation of retroviral RNAs.

Mutational analysis of the 5' leader region of simian foamy virus type 1

The sequence within the 5' untranslated region of the retroviral genome contains important cis elements for many steps in viral replication. There is limited information available on the role of this region in foamy virus replication. Similar to other retroviruses, the 5' untranslated region of foamy viruses predicts extensive RNA secondary structure. Serial mutations that could change parts of the predicted secondary structure were introduced in the 5' leader sequence including the R-U5 region of simian foamy virus type 1 (SFV-1) to investigate their role in virus genome packaging and virus replication. Point mutations in the R-U5 regions at nucleotide positions 7-12 (I), 241-243 (B), and 256-257 (D) had no effect on virus replication. Base substitution mutation at positions 193-195 (C), however, severely impaired virus replication. Deletion of sequences in the leader region, between the primer-binding site and the gag gene, at positions 364-399 (d1), 397-435 (d2), or 364-435 (d3), which included sequences for RNA genome dimerization, also blocked SFV-1 replication. Interestingly, none of these mutations affected genome packaging or the synthesis of viral transcripts, suggesting that a step(s) of virus replication following packaging is affected. The region between the primer-binding site and the gag gene, therefore, is not essential for foamy virus genome packaging. Furthermore, the cis-acting elements for genome dimerization and packaging appear to be localized in separate regions for foamy viruses.

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.

The leader of the HIV-1 RNA genome forms a compactly folded tertiary structure

The untranslated leader of the RNA genome of the human immunodeficiency virus type 1 (HIV-1) encodes multiple signals that regulate distinct steps of the viral replication cycle. The RNA secondary structure of several replicative signals in the HIV-1 leader is critical for function. Well-known examples include the TAR hairpin that forms the binding site for the viral Tat trans-activator protein and the DIS hairpin that is important for dimerization and subsequent packaging of the viral RNA into virion particles. In this study, we present evidence for the formation of a tertiary structure by the complete HIV-1 leader RNA. This conformer was recognized as a fast-migrating band on nondenaturing polyacrylamide gels, and such a migration effect is generally attributed to differences in compactness. Both the 5' and 3' domains of the 335-nt HIV-1 leader RNA are required for the formation of the compact RNA structure, and the presence of several putative interaction domains was revealed by an extensive analysis of the denaturing effect of antisense DNA oligonucleotides. The buffer conditions and sequence requirements for conformer formation are strikingly different from that of the RNA-dimerization reaction. In particular, the conformer was destabilized in the presence of Mg2+ ions and by the viral nucleocapsid (NC) protein. The presence of a stable RNA structure in the HIV-1 leader was also apparent when this RNA was used as template for reverse transcription, which yielded massive stops ahead of the structured leader domain. Formation of the conformer is a reversible event, suggesting that the HIV-1 leader is a dynamic molecule. The putative biological function of this conformational polymorphism as molecular RNA switch in the HIV-1 replication cycle is discussed.

RNA dimerization defect in a Rous sarcoma virus matrix mutant

The retrovirus matrix (MA) sequence of the Gag polyprotein has been shown to contain functions required for membrane targeting and binding during particle assembly and budding. Additional functions for MA have been proposed based on the existence of MA mutants in Rous sarcoma virus (RSV), murine leukemia virus, human immunodeficiency virus type 1, and human T-cell leukemia virus type 1 that lack infectivity even though they release particles of normal composition. Here we describe an RSV MA mutant with a surprising and previously unreported phenotype. In the mutant known as Myr1E, the small membrane-binding domain of the Src oncoprotein has been added as an N-terminal extension of Gag. While Myr1E is not infectious, full infectivity can be reestablished by a single amino acid substitution in the Src sequence (G2E), which eliminates the addition of myristic acid and the membrane-binding capacity of this foreign sequence. The presence of myristic acid at the N terminus of the Myr1E Gag protein does not explain its replication defect, because other myristylated derivatives of RSV Gag are fully infectious (e.g., Myr2 [C. R. Erdie and J. W. Wills, J. Virol. 64:5204-5208, 1990]). Biochemical analyses of Myr1E particles reveal that they contain wild-type levels of the Gag cleavage products, Env glycoproteins, and reverse transcriptase activity when measured on an exogenous template. Genomic RNA incorporation appears to be mildly reduced compared to the wild-type level. Unexpectedly, RNA isolated from Myr1E particles is monomeric when analyzed on nondenaturing Northern blots. Importantly, the insertional mutation does not lie within previously identified dimer linkage sites. In spite of the dimerization defect, the genomic RNA from Myr1E particles serves efficiently as a template for reverse transcription as measured by an endogenous reverse transcriptase assay. In marked contrast, after infection of avian cells, the products of reverse transcription are nearly undetectable. These findings might be explained either by the loss of a normal function of MA needed in the formation or stabilization of RNA dimers or by the interference in such events by the mutant MA molecules. It is possible that Myr1E viruses package a single copy of viral RNA.

An Mpsi-containing heterologous RNA, but not env mRNA, is efficiently packaged into avian retroviral particles

Retroviruses preferentially package full-length genomic RNA over spliced viral messages. For most retroviruses, this preference is likely due to the absence of all or part of the packaging signal on subgenomic RNAs. In avian leukosis-sarcoma virus, however, we have shown that the minimal packaging signal, MPsi, is located upstream of the 5' splice site and therefore is present on both genomic and spliced RNAs. We now show that an MPsi-containing heterologous RNA is packaged only 2.6-fold less efficiently than genomic Rous sarcoma virus RNA. Thus, few additional packaging sequences and/or structures exist outside of MPsi. In contrast, we found that env mRNA is not efficiently packaged. These results indicate that either MPsi is not functional on this RNA or the RNA is somehow segregated from the packaging machinery. Finally, deletion of sequences from the 3' end of MPsi was found to reduce the packaging efficiency of heterologous RNAs.

Studies of the genomic RNA of leukosis viruses: implications for RNA dimerization

Retroviral particles contain two positive-strand genomic RNAs linked together by noncovalent bonds that can be dissociated under mild conditions. We studied genomic RNAs of wild-type and mutant avian leukosis viruses (ALVs) in an attempt to (i) better understand the site(s) of RNA dimerization, (ii) examine whether the primer binding site (PBS) and tRNA primer are involved in dimerization, and (iii) determine the structure of genomic RNA in protease-deficient (PR(-)) mutants. We showed that extensively nicked wild-type ALV genomic RNAs melt cooperatively. This implies a complex secondary and/or tertiary structure for these RNAs that extends well beyond the 5' dimerization site. To investigate the role of the PBS-tRNA complex in dimerization, we analyzed genomic RNAs from mutant viruses in which the tRNA(Trp) PBS had been replaced with sequences homologous to the 3' end of six other chicken tRNAs. We found the genomic RNAs of these viruses are dimers that dissociate at the same temperature as wild-type viral RNA, which suggests that the identity of the PBS and the tRNA primer do not affect dimer stability. We studied two ALV PR(-) mutants: one containing a large (>1.9-kb) inversion spanning the 3' end of gag and much of pol, rendering it deficient in PR, reverse transcriptase, and integrase, and another with a point mutation in PR. In both of these mutant viruses, the genomic RNA appears to be either primarily or exclusively monomeric. These data suggest that ALV can package its RNA as monomers that subsequently dimerize.

An additional dimer linkage structure in Moloney murine leukemia virus RNA

We have identified an additional dimerization linkage structure in the genome of Moloney murine leukemia virus (MoMLV). Retroviral genomes have long been known to be linked at their 5' ends to form dimers. In MoMLV, a hairpin loop functioning as a dimer linkage structure (DLS) has previously been identified at nucleotides 278-303. Here, we describe RNA dimers formed from sections of the MoMLV 5' untranslated region that do not contain the previously described MoMLV DLS. These dimers exhibit the distinctive characteristics previously described for whole genome dimers. We have mapped this novel region to nucleotides 199-243. This sequence contains a stem-loop structure (nucleotides 204-227) much like the 278-303 region. We describe the chemical and thermal stability of dimers containing the 204-227 stem-loop as well as kinetics and salt-dependence of dimer formation. Our results show that dimerization of MoMLV RNA can be nucleated at multiple sites and suggest that the 5' untranslated region may contain separately folding and dimerizing domains.