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

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.

Actinomycin D inhibition of DNA strand transfer reactions catalyzed by HIV-1 reverse transcriptase and nucleocapsid protein

Actinomycin D was found to be a potent inhibitor of HIV-1 reverse transcriptase catalyzed DNA strand transfer reactions. Using an oligonucleotide model system, actinomycin D inhibition of DNA strand transfer was examined to elucidate the mechanism of inhibition and further define the mechanism of DNA strand transfer. Our results show that actinomycin D inhibits HIV-1 reverse transcriptase catalyzed DNA strand transfer without inhibiting RNA-dependent or DNA-dependent DNA polymerase activity. Actinomycin D was found to strongly inhibit annealing of a primary DNA product to the DNA acceptor template, preventing the formation of a key reaction intermediate. The HIV-1 nucleocapsid protein has been shown to participate in catalytic events during reverse transcription including DNA strand transfer. Recombinant nucleocapsid protein was used in conjunction with actinomycin D in this model system to investigate how NC may participate in the mechanism of inhibition by actinomycin D and in DNA strand transfer. The inclusion of nucleocapsid protein was found to partially relieve both DNA annealing and strand transfer inhibition caused by actinomycin D. This study suggests a potential new mechanism for inhibiting retroviral replication by preventing the formation of replication intermediates.

The native structure of the human immunodeficiency virus type 1 RNA genome is required for the first strand transfer of reverse transcription

Retroviral particles contain two genomic RNAs of approximately 9 kb that are linked in a noncovalent manner. In vitro studies with purified transcripts have identified particular RNA motifs that contribute to the RNA-dimerization reaction, but the situation may be more complex within virion particles. In this study, we tested whether the primer-binding site (PBS) of the human immunodeficiency virus type 1 (HIV-1) RNA genome and the associated tRNA(Lys3) primer play a role in the process of RNA dimerization. Deletion of the PBS motif did not preclude the formation of RNA dimers within virus particles, indicating that this motif and the tRNA primer do not participate in the interactions that control RNA packaging and dimerization. Genome dimerization has been proposed to play a role in particular steps of the reverse transcription mechanism. To test this, reverse transcription was performed with the native RNA dimer and the heat-denatured template. These two template forms yielded equivalent levels of minus-strand strong-stop cDNA product, which is an early intermediate of reverse transcription. However, melting of the RNA dimer precluded the next step of reverse transcription, in which the minus-strand strong-stop cDNA is translocated from the 5' repeat element to the 3' repeat element. The results suggest that the conformation of the dimeric RNA genome facilitates the first strand-transfer reaction of the reverse transcription mechanism.

Sequences in pol are required for transfer of human foamy virus-based vectors

A series of vectors with heterologous genes was constructed from HSRV1, an infectious clone of human foamy virus (HFV), and transfected into baby hamster kidney cells to generate stably transfected vector cell lines. Two cis-acting sequences were required to achieve efficient rescue by helper virus. The first element was located at the 5' end upstream of position 1274 of the proviral DNA. Interestingly, a mutation in the leader sequence which decreased the ability to dimerize in vitro inhibited transfer by helper HFV. A second element that was important for vector transfer was located in the pol gene between positions 5638 and 6317. Constructs lacking this element were only poorly transferred by helper HFV, even though their RNA was produced in the vector cell lines. This finding rules out the possibility that the observed lack of transfer was due to RNA instability. A minimal vector containing only these two elements could be successfully delivered by helper HFV, confirming that all essential cis-acting sequences were present. The presence of a sequence described as a second polypurine tract in HFV was not necessary for transfer. Our data identified the minimal sequence requirements for HFV vector transfer for the development of useful vector systems.

Improved envelope function selected by long-term cultivation of a translation-impaired HIV-1 mutant

The untranslated leader region of the human immunodeficiency virus (HIV) RNA genome contains multiple regulatory elements that fold into stable hairpin structures. Because extensive secondary structure can block the scanning of ribosomes, an alternative mechanism for HIV translation seems feasible. To study the mechanism of HIV-1 mRNA translation, a start codon was introduced in the leader region that will usurp scanning ribosomes. This upstream AUG mutation (uAUG) inhibited HIV gene expression, indicating that HIV-1 mRNA translation occurs via the regular scanning mechanism. Revertant viruses with increased replication capacity were obtained upon prolonged culturing of the mutant virus. To our surprise, the introduced start codon had not been inactivated in these phenotypic revertants. Instead, these revertants contain additional mutations in the envelope (Env) protein that stimulated HIV-1 replication. These second-site Env mutations did not specifically overcome the gene expression defect of the uAUG mutant, as the replication capacity of other HIV-1 mutants with an unrelated defect could also be improved. The uAUG construct appears to be a unique tool in forced HIV-1 adaptation studies because the deleterious uAUG mutation is stably maintained in the progeny, yielding phenotypic revertants with second-site mutations elsewhere in the viral genome.

Infectious molecular clones with the nonhomologous dimer initiation sequences found in different subtypes of human immunodeficiency virus type 1 can recombine and initiate a spreading infection in vitro

Recombinant forms of human immunodeficiency virus type 1 (HIV-1) have been shown to be of major importance in the global AIDS pandemic. Viral RNA dimer formation mediated by the dimerization initiation sequence (DIS) is believed to be essential for viral genomic RNA packaging and therefore for RNA recombination. Here, we demonstrate that HIV-1 recombination and replication are not restricted by variant DIS loop sequences. Three DIS loop forms found among HIV-1 isolates, DIS (CG), DIS (TA), and DIS (TG), when introduced into deletion mutants of HIV-1 recombined efficiently, and the progeny virions replicated with comparable kinetics. A fourth DIS loop form, containing an artificial AAAAAA sequence disrupting the putative DIS loop-loop interactions [DIS (A6)], supported efficient recombination with DIS loop variants; however, DIS (A6) progeny virions exhibited a modest replication disadvantage in mixed cultures. Our studies indicate that the nonhomologous DIS sequences found in different HIV-1 subtypes are not a primary obstacle to intersubtype recombination.

Dimerization of MoMuLV genomic RNA: redefinition of the role of the palindromic stem-loop H1 (278-303) and new roles for stem-loops H2 (310-352) and H3 (355-374)

Genomic RNAs from retroviruses are packaged as dimers of two identical RNA molecules. In Moloney murine leukemia virus, a stem-loop structure (H1) located in the encapsidation domain Psi (nucleotides 215-564) was postulated to trigger RNA dimerization through base pairing between auto complementary sequences. The Psi domain also contains two other stem-loop structures (H2 and H3) that are essential for RNA packaging. Since it was suspected than H1 is not the only element involved in RNA dimerization, we systematically investigated the dimerization capacity of several subdomains of the first 725 nucleotides of genomic RNA. The efficiency of dimerization of the various RNAs was estimated by measuring their apparent dissociation constants, and the specificity was tested by competition experiments. Our results indicate that the specificity of dimerization of RNA nucleotides 1-725 is driven by motifs H1-H3 in domain Psi. To define the relative contributions of these elements, RNA deletion mutants containing different combinations of H1-H3 were constructed and further analyzed in competition and kinetic experiments. Our results confirm the importance of H1 in triggering dimerization and shed new light on the mechanism of dimerization. H1 is required to provide a stable dimer, probably through the formation of extended intermolecular interactions. However, H1-mediated association is a slow process that is kinetically enhanced by H3, and to a lesser extent by H2. We suggest that they facilitate the recognition between the two RNAs, most likely through their conserved GACG loops. Our results reinforce the idea that dimerization and packaging are two closely related processes.

Mutational analysis of stem-loops in the RNA packaging signal of the Moloney murine leukemia virus

The retroviral RNA genome is targeted for incorporation into the nascent virion particle by the psi region, a specific block of RNA sequences near the 5' end. A number of deletions and linker insertion mutations were introduced into the psi region of cloned DNA of the Moloney murine leukemia virus, and the mutants were introduced into cells in culture and tested for their ability to direct the assembly of virions and the packaging of viral RNA. Only a small portion of the psi region was important for packaging, containing the so-called stem-loops C and D. Additional mutants were used to demonstrate that the base pairing of stem D, and the sequence of loop D, were essential for normal packaging of the RNA. Two mutants with alterations near the 5' splice donor were also replication-defective, probably due to effects on gene expression. The results allow a high-resolution definition of the RNA structures required during virus replication in culture.

The bovine leukemia virus encapsidation signal is composed of RNA secondary structures

The encapsidation signal of bovine leukemia virus (BLV) was previously shown by deletion analysis to be discontinuous and to extend into the 5' end of the gag gene (L. Mansky et al., J. Virol. 69:3282-3289, 1995). The global minimum-energy optimal folding for the entire BLV RNA, including the previously mapped primary and secondary encapsidation signal regions, was analyzed. Two stable stem-loop structures (located just downstream of the gag start codon) were predicted within the primary signal region, and one stable stem-loop structure (in the gag gene) was predicted in the secondary signal region. Based on these predicted structures, we introduced a series of mutations into the primary and secondary encapsidation signals in order to explore the sequence and structural information contained within these regions. The replication efficiency and levels of cytoplasmic and virion RNA were analyzed for these mutants. Mutations that disrupted either or both of the predicted stem-loop structures of the primary signal reduced the replication efficiency by factors of 7 and 40, respectively; similar reductions in RNA encapsidation efficiency were observed. The mutant with both stem-loop structures disrupted had a phenotype similar to that of a mutant containing a deletion of the entire primary signal region. Mutations that disrupted the predicted stem-loop structure of the secondary signal led to similar reductions (factors of 4 to 6) in both the replication and RNA encapsidation efficiencies. The introduction of compensatory mutations into mutants from both the primary and secondary signal regions, which restored the predicted stem-loop structures, led to levels of replication and RNA encapsidation comparable to those of virus containing the wild-type encapsidation signal. Replacement of the BLV RNA region containing the primary and secondary encapsidation signals with a similar region from human T-cell leukemia virus (HTLV) type 1 or type 2 led to virus replication at three-quarters or one-fifth of the level of the parental virus, respectively. The results from both the compensatory mutants and BLV-HTLV chimeras indicate that the encapsidation sequences are recognized largely by their secondary or tertiary structures.

RNAs from genetically distinct retroviruses can copackage and exchange genetic information in vivo

Sequence analysis suggests that ancient recombination events may have occurred between genetically distinct retroviruses. An experimental system was utilized to explore the genetic interaction between different viruses. Moloney murine sarcoma virus and spleen necrosis virus are type C retroviruses that belong to different subgenera. With vectors containing packaging signals from these two viruses, DNA proviruses containing genetic information from both RNAs can be generated. This is the first experimental evidence to indicate that RNA from different retroviruses can copackage and exchange genetic information.

Non-canonical interactions in a kissing loop complex: the dimerization initiation site of HIV-1 genomic RNA

Retroviruses encapsidate two molecules of genomic RNA that are noncovalently linked close to their 5' ends in a region called the dimer linkage structure (DLS). The dimerization initiation site (DIS) of human immunodeficiency virus type 1 (HIV-1) constitutes the essential part of the DLS in vitro and is crucial for efficient HIV-1 replication in cell culture. We previously identified the DIS as a hairpin structure, located upstream of the major splice donor site, that contains in the loop a six-nucleotide self-complementary sequence preceded and followed by two and one purines, respectively. Two RNA monomers form a kissing loop complex via intermolecular interactions of the six nucleotide self-complementary sequence. Here, we introduced compensatory mutations in the self-complementary sequence and/or a mutation in the flanking purines. We determined the kinetics of dimerization, the thermal stabilities and the apparent equilibrium dissociation constants of wild-type and mutant dimers and used chemical probing to obtain structural information. Our results demonstrate the importance of the 5'-flanking purine and of the two central bases of the self-complementary sequence in the dimerization process. The experimental data are rationalized by triple interactions between these residues in the deep groove of the kissing helix and are incorporated into a three-dimensional model of the kissing loop dimer. In addition, chemical probing and molecular modeling favor the existence of a non-canonical interaction between the conserved adenine residues at the first and last positions in the DIS loop. Furthermore, we show that destabilization of the kissing loop complex at the DIS can be compensated by interactions involving sequences located downstream of the splice donor site of the HIV-1 genomic RNA.

Inhibition of HIV type 1 RNA dimerization by antisense DNA corresponding to the 17-nucleotide sequence downstream from the splice donor site of HIV type 1 RNA

HIV-1 RNA dimerization involves at least two key regions, one located upstream from the splice donor (SD) site, and the other located downstream from the SD site. To determine the precise location and the mechanism of action of the downstream region, we constructed a model system using a synthetic HIV-1 RNA fragment (HXB2, 455-1146), which dimerized at relatively low salt concentrations (100 mM KCl, 1 mM MgCl2). We tested in this system antisense DNAs that are complementary to both the upstream and downstream regions of HIV-1 RNA for their possible inhibitory effects on dimerization. Antisense DNAs complementary to nucleotides 773-789 located downstream from the SD site effectively inhibited dimerization of HIV-1 RNA. These inhibitory antisense DNAs hybridized with the dimer form of HIV-1 RNA, and dissociated the dimer into monomers. However, antisense DNAs complementary to the region upstream from the SD site did not hybridize with the dimer, although they inhibited RNA dimerization and also dissociated the preformed dimer.

Effect of mutations in the nucleocapsid protein (NCp7) upon Pr160(gag-pol) and tRNA(Lys) incorporation into human immunodeficiency virus type 1

COS-7 cells were transfected with DNAs containing mutations in the NCp7 sequences of human immunodeficiency virus. Selective incorporation into the virus of tRNA(Lys) was measured by two-dimensional polyacrylamide gel electrophoresis, and Pr160(gag-pol) incorporation into the virus was detected in Western blots of viral protein. Mutations tested included cysteine and histidine mutations in either of the Cys-His boxes, as well as mutations in the N- and C-terminal flanking regions and in the linker region between the two Cys-His boxes. Of 10 mutations tested, only 2 inhibited tRNA(Lys) incorporation: a P31L mutation in the linker region and a deletion which removed both Cys-His boxes and the linker region (deltaK14-T50). The P31L mutation prevents the incorporation of Pr160(gag-pol) into the virus. Cotransfection of COS cells with both P31L DNA and a plasmid coding only for unprocessed Pr160(gag-pol) resulted in the viral incorporation of Pr160(gag-pol) and the rescue of selective packaging of tRNA(Lys) into the virion. In the deltaK14-T50 mutant, Pr160(gag-pol) is incorporated into the virus. Selective tRNA(Lys) packaging is not rescued by cotransfection with a plasmid coding for Pr160(gag-pol) but is rescued by cotransfection with DNA coding for wild-type Pr55(gag). Since Pr55(gag) does not by itself selectively package tRNA(Lys), the deltaK14-T50 mutation may be affecting tRNA(Lys) binding to a cytoplasmic Pr55(gag)/Pr160(gag-pol) complex.

Human immunodeficiency virus type 1 RNA outside the primary encapsidation and dimer linkage region affects RNA dimer stability in vivo

To characterize the cis-acting determinants that function in RNA dimer formation and maintenance, we examined the stability of RNA dimers isolated from virus particles containing mutations in the encapsidation region of human immunodeficiency virus type 1 (HIV-1). The genomic RNAs of all mutants containing lesions in elements required for in vitro dimerization exhibited thermal stability similar to that of wild-type (WT) HIV-1. These data indicate that the eventual formation of stable dimeric RNA in vivo is not absolutely dependent on the elements that promote dimer formation in vitro. Surprisingly, mutants that lacked a large segment of the middle portion of the genome, outside the likely primary dimer linkage region, formed RNA dimers that were measurably more stable than WT. In addition, the insertion of one or multiple copies of a foreign gene, which resulted in a series of vectors that approached RNA length similar to that of WT RNA, still exhibited augmented dimer stability. These results suggest that there are regions in the HIV-1 genome outside the primary dimer initiation and dimer linkage regions that can negatively affect dimer stability.

Identification of sites that act together to direct dimerization of human foamy virus RNA in vitro

Retroviral particles contain two molecules of genomic RNA, which are noncovalently linked near their 5' ends in a region called the dimer linkage structure (DLS). By using complementary DNA oligonucleotides and deletion mutants to impair RNA dimerization of the human foamy virus (HFV), three sites, designated SI, SII, and SIII, were found within a 159-nucleotide RNA fragment of HFV that are involved in dimerization in vitro. SI overlaps the primer-binding site; and SII contains the palindromic sequence, UCCCUAGGGA, the disruption of which impairs dimer formation; and SIII extends into the gag gene. The first two sites are highly conserved in the other primate foamy viruses, SFV-1, SFV-3, and SFVcpz, whereas the third appears to be shared only by HFV and SFVcpz. RNA of HFV and SFV-3 could form heterodimers, indicating that both viruses dimerize by similar mechanisms. On testing thermal stability, dimers of the 159-nucleotide fragment dissociated between 40 and 70 degrees, with half of the dimers dissociating at 55 degrees. Since the splice donor site of HFV is located at position 51 of viral RNA, the DLS is part of the genomic RNA exclusively.

Position dependence of functional hairpins important for human immunodeficiency virus type 1 RNA encapsidation in vivo

At least two hairpins in the 5' untranslated leader region, stem-loops 1 and 3 (SL1 and SL3), contribute to human immunodeficiency virus type 1 RNA encapsidation in vivo. We used a competitive assay, which measures the relative encapsidation efficiency of mutant viral RNA in the presence of competing wild-type RNA, to compare the contributions of SL1, SL3, and two adjacent secondary structures, SL2 and SL4, to encapsidation. SL2 is not required for RNA encapsidation, while SL1, SL3, and SL4 all contribute approximately equally to encapsidation. To determine whether these hairpins function in a position-dependent manner, we interchanged the positions of two of these stem-loop structures. This resulted in substantial diminution of encapsidation, indicating that the secondary structures that comprise E, the encapsidation signal, function only in their correct contexts. Mutation of nucleotides flanking SL1 and SL3 had little effect on encapsidation. We also showed that SL1, while present on both genomic and subgenomic viral RNAs, nonetheless contributes to selective encapsidation of genomic RNA. Taken together, these data are consistent with the formation of a higher-order RNA structure, partially composed of SL1, SL3, and SL4, that functions to effect concurrent encapsidation of full-length RNA and exclusion of subgenomic RNA. Finally, it has been reported that E is required for efficient translation of Gag mRNA in vivo. However, we have found that a variety of mutants, including a mutant lacking the entire region encompassing SL1, SL2, and SL3, still produce RNAs that are efficiently translated. These data indicate that E is unlikely to contribute to efficient Gag mRNA translation in vivo.

Two step synthesis of (-) strong-stop DNA by avian and murine reverse transcriptases in vitro

Retroviral reverses transcriptases (RTs) are RNA- and DNA-dependent DNA polymerases that use a tRNA bound at the so-called primer binding site (PBS) located near the 5'end of the genomic RNA as primer. Thus, RTs must be able to accommodate both RNA and DNA in the primer strand. To test whether the natural primer confers some advantages to the priming process, we compared initiation of reverse transcription of avian and murine retroviral RNAs, using either their natural tRNA primer, tRNATrp and tRNAPro, respectively, or synthetic 18mer oligodeoxyribonucleotides (ODNs) and oligoribonucleotides (ORNs) complementary to their PBS. In both retroviral systems, the initial extension of ODNs was fast and processive. The initial extension of ORNs, tRNATrp and tRNAPro was much slower and distributive, giving rise to the transient accumulation of short pausing products. Synthesis of (-) strong-stop DNA was delayed when using ORNs and tRNAs, compared to ODNs. Even though ORNs and tRNAs were initially extended at the same rate, the short pausing products were more rapidly extended when using the tRNA primers. As a consequence, synthesis of (-) strong-stop DNA was much more efficient with tRNA primers, compared to ORNs. Taken together, these results suggest that the tRNA-primed synthesis of (-) strong-stop DNA is a two-step process, as already observed for HIV-1. The initiation mode corresponds to the initial non-processive nucleotide addition and extension of the short pausing products. It is more efficient with the natural primers than with ORNs. Initiation is followed by a more processive and unspecific elongation mode. Elongation is observed when the primer strand is DNA, i.e. when using the ODNs as primers or when the ORN and tRNA primers have been extended by a sufficient number (depending on the retroviral system) of deoxyribonucleotides.

A dual role of the putative RNA dimerization initiation site of human immunodeficiency virus type 1 in genomic RNA packaging and proviral DNA synthesis

In retroviruses, the genomic RNA is in the form of a 60S-70S complex composed of two identical genome-length RNA molecules tightly associated through numerous interactions. A major interaction, called the dimer linkage structure, has been found near the RNA 5' end and is probably involved in the control of translation, packaging, and recombination during proviral DNA synthesis. Recently, a small sequence corresponding to a stem-loop structure located in the 5' leader of human immunodeficiency virus type 1 (HIV-1) RNA was found to be required for the initiation of HIV-1 RNA dimerization in vitro and named the dimerization initiation site (E. Skripkin, J.-C. Paillart, R. Marquet, B. Ehresmann, and C. Ehresmann, Proc. Natl. Acad. Sci. USA 91: 4945-4949, 1994). To investigate the possible role of this 5' stem-loop in HIV-1 virion formation and infectivity, four mutant viruses were generated and analyzed in vivo. Results show that deletion of the stem-loop structure reduces infectivity by a factor of 10(3) whereas loop substitutions cause a decrease of 10- to 100-fold. The level of genomic RNA packaging was found to be decreased fivefold in mutants virions containing the stem-loop deletion and only twofold in the loop-substituted virions. Surprisingly, the second DNA strand transfer during reverse transcription was found to be severely impaired upon stem-loop deletion. Taken together, these results indicate that the stem-loop structure called the dimerization initiation site is a cis element acting on both genomic RNA packaging and synthesis of proviral DNA.

Mechanisms of inhibition of in vitro dimerization of HIV type I RNA by sense and antisense oligonucleotides

Retroviruses display a strong selective pressure to maintain the dimeric nature of their genomic RNAs, suggesting that dimerization is essential for viral replication. Recently, we identified the cis-element required for initiation of human immunodeficiency virus type I (HIV-I) RNA dimerization in vitro. The dimerization initiation site (DIS) is a hairpin structure containing a self-complementary sequence in the loop. We proposed that dimerization is initiated by a loop-loop kissing interaction involving the self-complementary sequence present in each monomer. We tested the ability of sense and antisense oligonucleotides targeted against the DIS to interfere with a preformed viral RNA dimer. Self-dimerization and inhibition properties of the tested oligonucleotides are dictated by the nature of the loop. An RNA loop is absolutely required in the case of sense oligonucleotides, whereas the nature and the sequence of the stem is not important. They form reversible loop-loop interactions and act as competitive inhibitors. Antisense oligonucleotides are less efficient in self-dimerization and are more potent inhibitors than sense oligonucleotides. They are less sensitive to the nature of the loop than the antisense oligonucleotides. Antisense hairpins with either RNA or DNA stems are able to form highly stable and irreversible complexes with viral RNA, resulting from complete extension of base pairing initiated by loop-loop interaction.

Role of the DIS hairpin in replication of human immunodeficiency virus type 1

The virion-associated genome of human immunodeficiency virus type 1 consists of a noncovalently linked dimer of two identical, unspliced RNA molecules. A hairpin structure within the untranslated leader transcript is postulated to play a role in RNA dimerization through base pairing of the autocomplementary loop sequences. This hairpin motif with the palindromic loop sequence is referred to as the dimer initiation site (DIS), and the type of interaction is termed loop-loop kissing. Detailed phylogenetic analysis of the DIS motifs in different human and simian immunodeficiency viruses revealed conservation of the hairpin structure with a 6-mer palindrome in the loop, despite considerable sequence divergence. This finding supports the loop-loop kissing mechanism. To test this possibility, proviral genomes with mutations in the DIS palindrome were constructed. The appearance of infectious virus upon transfection into SupT1 T cells was delayed for the DIS mutants compared with that obtained by transfection of the wild-type provirus (pLAI), confirming that this RNA motif plays an important role in virus replication. Surprisingly, the RNA genome extracted from mutant virions was found to be fully dimeric and to have a normal thermal stability. These results indicate that the DIS motif is not essential for human immunodeficiency virus type 1 RNA dimerization and suggest that DIS base pairing does not contribute to the stability of the mature RNA dimer. Instead, we measured a reduction in the amount of viral RNA encapsidated in the mutant virions, suggesting a role of the DIS motif in RNA packaging. This result correlates with the idea that the processes of RNA dimerization and packaging are intrinsically linked, and we propose that DIS pairing is a prerequisite for RNA packaging.

Interaction of retroviral nucleocapsid proteins with transfer RNAPhe: a lead ribozyme and 1H NMR study

In the initiation of reverse transcription in retroviruses, nucleocapsid (NC) protein accelerates the rate of annealing of transfer RNA replication primer to a complementary sequence on the genomic RNA. In this report, we have probed the conformational changes induced by HIV-1 NC protein and domain deletion mutants in a structurally well-characterized transfer RNA, yeast tRNAPhe, as a model for the natural primer. One molar equivalent of recombinant 71 amino acid HIV-1 nucleocapsid protein (NC 1-71) is sufficient to completely inhibit the Pb2(+)-ribozyme activity of tRNAPhe at 25 degrees C, pH 7.0 and 15 mM MgCl2, Zn2 HIV-1 NC proteins which lack one or both flexible terminal domains also inhibit the ribozyme activity. 1H NMR spectra acquired for Mg(2+)-tRNAPhe suggest that NC 1-71 and NC 12-55 (lacking residues 1-11 and 56-71) inhibit the lead-ribozyme activity by only modestly altering the active site region rather than inducing large-scale unfolding of the molecule. In the absence of Mg2+, the extent of destabilization of tRNAPhe is greater but appears to be confined to internal regions of the acceptor and T psi C helices, as evidenced by the selectively enhanced exchange rates for imino protons associated with these base pairs. These findings show that NC destabilizes the folded form of tRNAPhe and by extension, other complex RNAs, in tertiary and secondary structural regions most susceptible to thermally-induced denaturation.

cis-active structural motifs involved in specific encapsidation of Moloney murine leukemia virus RNA

We have analyzed the roles of RNA structural motifs located in the 5' part of the Moloney murine leukemia virus (M-MuLV) encapsidation domain (Psi region) with regard to their effects on viral replication. Four putative stem-loop structures between the 5' splice donor site and the gag initiation codon have been examined: stem structure A, corresponding to M-MuLV viral nucleotides 211 to 224; stem-loop B, nucleotides 278 to 303; stem-loop C, nucleotides 310 to 352; and stem-loop D, nucleotides 355 to 374. By measuring infectivities, encapsidation and splicing efficiencies, and endogenous reverse transcription levels of motif A, B, C, and D deletion mutants, we identified mutations which affect replication at the encapsidation step. In particular, deletion of all four motifs in a single mutant eliminated encapsidation of viral RNA, while deletion of individual elements moderately reduced the encapsidation efficiencies. Through analysis of different deletion combinations, we found that deletion of the first two motifs (A plus B) reduced both encapsidation and reverse transcription efficiencies, while deletion of the 3' motifs (C plus D) eliminated encapsidation. Interestingly, the C and D motifs both contain a GACG loop sequence and are highly conserved among murine type C retroviruses. Our results indicate that M-MuLV motifs C and D are necessary for efficient encapsidation, and the presence of at least one of these two stem-loops is crucial to encapsidation and virus replication.

HIV-1 nucleocapsid protein induces "maturation" of dimeric retroviral RNA in vitro

After a retrovirus particle is released from the cell, the dimeric genomic RNA undergoes a change in conformation. We have previously proposed that this change, termed maturation of the dimer, is due to the action of nucleocapsid (NC) protein on the RNA within the virus particle. We now report that treatment of a 345-base synthetic fragment of Harvey sarcoma virus RNA with recombinant or synthetic HIV-1 NC protein converts a less stable form of dimeric RNA to a more stable form. This phenomenon thus appears to reproduce the maturation of dimeric retroviral RNA in a completely defined system in vitro. To our knowledge, maturation of dimeric RNA within a retrovirus particle is the first example of action of an "RNA chaperone" protein in vivo. Studies with mutant NC proteins suggest that the activity depends upon basic amino acid residues flanking the N-terminal zinc finger and upon residues within the N-terminal finger, including an aromatic amino acid, but do not require the zinc finger structures themselves.

The use of chemical modification interference and inverse PCR mutagenesis to identify the dimerization initiation site of HIV-1 genomic RNA

The retroviral genome consists of two identical RNA molecules physically linked together close to their 5' end, in a region called the Dimer Linkage Structure (DLS). Recent findings suggest that dimerization is involved in encapsidation, regulation of translation and reverse transcription. Previous in vitro studies localized the DLS of HIV-1 in a region downstream of the splice donor (SD) site. More recently, we showed that dimerization of HIV-1 RNA also involves sequences upstream of the SD site. Modification interference experiments and site-directed mutagenesis were used to identify the nucleotides required in the dimerization process of HIV-1 RNA. Our results point out a self-complementary sequence located in a hairpin loop, between the Primer Binding Site (PBS) and the SD site, as the Dimerization Initiation Site.

A loop-loop "kissing" complex is the essential part of the dimer linkage of genomic HIV-1 RNA

RNA-RNA interactions govern a number of biological processes. Several RNAs, including natural sense and antisense RNAs, interact by means of a two-step mechanism: recognition is mediated by a loop-loop complex, which is then stabilized by formation of an extended intermolecular duplex. It was proposed that the same mechanism holds for dimerization of the genomic RNA of human immunodeficiency virus type 1 (HIV-1), an event thought to control crucial steps of HIV-1 replication. However, whereas interaction between the partially self-complementary loop of the dimerization initiation site (DIS) of each monomer is well established, formation of the extended duplex remained speculative. Here we first show that in vitro dimerization of HIV-1 RNA is a specific process, not resulting from simple annealing of denatured molecules. Next we used mutants of the DIS to test the formation of the extended duplex. Four pairs of transcomplementary mutants were designed in such a way that all pairs can form the loop-loop "kissing" complex, but only two of them can potentially form the extended duplex. All pairs of mutants form heterodimers whose thermal stability, dissociation constant, and dynamics were analyzed. Taken together, our results indicate that, in contrast with the interactions between natural sense and antisense RNAs, no extended duplex is formed during dimerization of HIV-1 RNA. We also showed that 55-mer sense RNAs containing the DIS are able to interfere with the preformed HIV-1 RNA dimer.

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.

Dimerization of retroviral genomic RNAs: structural and functional implications

Retroviruses are a family of widespread small animal viruses at the origin of a diversity of diseases. They share common structural and functional properties such as reverse transcription of their RNA genome and integration of the proviral DNA into the host genome, and have the particularity of packaging a diploid genome. The genome of all retroviruses is composed of two homologous RNA molecules that are non-covalently linked near their 5' end in a region called the dimer linkage structure (DLS). There is now considerable evidence that a specific site (or sites) in the 5' leader region of all retroviruses, located either upstream or/and downstream of the major splice donor site, is involved in the dimer linkage. For MoMuLV and especially HIV-1, it was shown that dimerization is initiated at a stem-loop structure named the dimerization initiation site (DIS). The DIS of HIV-1 and related regions in other retroviruses corresponds to a highly conserved structure with a self-complementary loop sequence, that is involved in a typical loop-loop 'kissing' complex which can be further stabilized by long distance interactions or by conformational rearrangements. RNA interactions involved in the viral RNA dimer were postulated to regulate several key steps in retroviral cycle, such as: i) translation and encapsidation: the arrest of gag translation imposed by the highly structured DLS-encapsidation signal would leave the RNA genome available for the encapsidation machinery; and ii) recombination during reverse transcription: the presence of two RNA molecules in particles would be necessary for variability and viability of virus progeny and the ordered structure imposed by the DLS would be required for efficient reverse transcription.

Human immunodeficiency virus nucleocapsid protein stimulates strand transfer from internal regions of heteropolymeric RNA templates

We have examined the influence of HIV nucleocapsid protein (NCp) on strand transfer from internal regions of a heteropolymeric RNA template. The system consisted of a DNA-primed 225 nucleotide RNA donor template, on which reverse transcriptase initiated primer extension, and a 189 nucleotide RNA acceptor template, to which extended primers could transfer. The last 133 nucleotides on the 3' end of the acceptor were homologous to an internal region on the donor, limiting homologous strand transfer to this region. Primers extended to the end of the donor were 212 nucleotides while those transferred to, and extended on the acceptor were 259 nucleotides in length. The rate of strand transfer and the level of transfer products increased several-fold when nucleocapsid was included in the reactions. The increase was due, at least in part, to the transfer to, and extension on the acceptor, of incompletely elongated primer-extension products that were "chased" into transfer products in the presence of nucleocapsid. Nucleocapsid did not directly influence reverse transcriptase elongation as the enzyme processivity (number of nucleotides incorporated before the enzyme dissociates from the primer-template) was approximately the same in the presence and absence of nucleocapsid.

An internal ribosomal entry signal in the rat VL30 region of the Harvey murine sarcoma virus leader and its use in dicistronic retroviral vectors

The genetic organization of the 5' genomic RNA domain of the highly oncogenic Harvey murine sarcoma virus appears to be unusual in that a multifunctional untranslated leader precedes the v-ras oncogene. This 5' leader is 1,076 nucleotides in length and is formed of independent regions involved in key steps of the viral life cycle: (i) the Moloney murine leukemia virus 5' repeat, untranslated 5' region, and primer binding site sequences necessary for the first steps of proviral DNA synthesis, (ii) the virus-like 30S (VL30)-derived sequence containing a functional dimerization-packaging signal (E/DLS) directing viral RNA dimerization and packaging into MLV virions, and (iii) an Alu-like sequence preceding the 5' untranslated sequence of v-rasH which contains the initiation codon of the p21ras oncoprotein. These functional features, the unusual length of this leader (1,076 nucleotides), and the presence of stable secondary structures between the cap and the v-ras initiation codon might well cause a premature stop of the scanning ribosomes and thus inhibit v-ras translation. In order to understand how Harvey murine sarcoma virus achieves a high level of expression of the ras oncogene, we asked whether the rat VL30 sequence, 5' to v-ras, could contribute to an efficient synthesis of the ras oncoprotein. The implications of the VL30 sequence in the translation initiation of Ha-ras were investigated in the rabbit reticulocyte lysate system and in murine cells. Results show that the rat VL30 sequence allows a cap-independent translation of a downstream reporter gene both in vitro and in murine cells. Additional experiments performed with dicistronic neo.VL30.lacZ mRNAs indicate that the 5' VL30 sequence (positions 380 to 794) contains an internal ribosomal entry signal. This finding led us to construct a new dicistronic retroviral vector with which the rat VL30 sequence was able to direct the efficient expression of a 3' cistron and packaging of recombinant dicistronic RNA into murine leukemia virus virions.

Alternative translation initiation of the Moloney murine leukemia virus mRNA controlled by internal ribosome entry involving the p57/PTB splicing factor

Moloney murine leukemia virus (Mo-MuLV) genomic mRNA codes for two gag precursors by alternative initiations of translation. An AUG codon governs the synthesis of the retroviral capsid proteins precursor, whereas a CUG codon directs the synthesis of a glycosylated cell surface antigen, the gross cell surface antigen. Control of the relative synthesis of the two precursors is crucial for MuLV infectivity and pathology. Furthermore, the MuLV mRNA leader sequence is very long and should inhibit translation according to the classical scanning model. This suggests a different translation initiation mechanism allowing gag efficient expression. We demonstrate, by using bicistronic vectors expressed in COS-7 cells, that the Mo-MuLV mRNA leader drives translation initiation by internal ribosome entry. We have localized the internal ribosome entry site (IRES) between the two initiation codons. This 126 nucleotide long IRES implies an oligopyrimidine tract located 45 nucleotides upstream of AUG codon. UV cross-linking and affinity chromatography experiments show that the PTB/p57 splicing factor specifically interacts with this oligopyrimidine tract. The MuLV IRES controls alternative translation initiation by activating the capsid protein precursor expression. This gag translational enhancer could exist in other retroviruses.

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.

Analysis of the nucleic acid annealing activities of nucleocapsid protein from HIV-1

Retroviral nucleocapsid (NC) protein is an integral part of the virion nucleocapsid where it is in tight association with genomic RNA and the tRNA primer. NC protein is necessary for the dimerization and encapsidation of genomic RNA, the annealing of the tRNA primer to the primer binding site (PBS) and the initial strand transfer event. Due to the general nature of NC protein-promoted annealing, its use to improve nucleic acid interactions in various reactions can be envisioned. Parameters affecting NC-promoted nucleic acid annealing of NCp7 from HIV-1 have been analyzed. The promotion of RNA:RNA and RNA:DNA annealing by NCp7 is more sensitive to the concentration of MgCl2 than the promotion of DNA:DNA hybridization. Stimulation of complex formation for all three complexes was efficient at 0-90 mM NaCl, between 23 and 55 degrees C and at pH values between 6.5 and 9.5, inclusive. Parameters affecting NCp7-promoted hybridization of tRNA(Lys,3) to the PBS, which appears to be specific for NC protein, will be discussed. Results implicate the basic regions of NCp7, but not the zinc fingers, in promoting the annealing of complementary nucleic acid sequences. Finally, NCp7 strand transfer activity aids the formation of the most stable nucleic acid complex.

The bovine leukemia virus encapsidation signal is discontinuous and extends into the 5' end of the gag gene

In order to define bovine leukemia virus (BLV) sequences required for efficient vector replication, a series of mutations were made in a BLV vector. Testing the replication efficiency of the vectors with a helper virus and helper plasmids allowed for separation of the mutant vectors into three groups. The replication efficiency of the first group was reduced by a factor of 7; these mutants contained deletions in the 5' end of the gag gene. The second group of mutants had replication reduced by a factor of 50 and had deletions including the 5' untranslated leader region. The third group of mutants replicated at levels comparable to those of the parental vector and contained deletions of the 3' end of the gag gene, the pol gene, and the env gene. Analysis of cytoplasmic and virion RNA levels indicated that vector RNA expression was not affected but that the vector RNA encapsidation was less efficient for group 1 and group 2 mutants. Additional mutations revealed two regions important for RNA encapsidation. The first region is a 132-nucleotide-base sequence within the gag gene (nucleotides 1015 to 1147 of the proviral DNA) and facilitates efficient RNA encapsidation in the presence of the second region. The second region includes a 147-nucleotide-base sequence downstream of the primer binding site (nucleotide 551) and near the gag gene start codon (nucleotide 698; gag begins at nucleotide 628) and is essential for RNA encapsidation. We conclude that the encapsidation signal is discontinuous; a primary signal, essential for RNA encapsidation, is largely in the untranslated leader region between the primer binding site and near the gag start codon. A secondary signal, which facilitates efficient RNA encapsidation, is in a 132-nucleotide-base region within the 5' end of the gag gene.

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.

Multiple regions of Harvey sarcoma virus RNA can dimerize in vitro

Retroviruses contain a dimeric RNA consisting of two identical molecules of plus-strand genomic RNA. The structure of the linkage between the two monomers is not known, but they are believed to be joined near their 5' ends. Darlix and coworkers have reported that transcripts of retroviral RNA sequences can dimerize spontaneously in vitro (see, for example, E. Bieth, C. Gabus, and J. L. Darlix, Nucleic Acids Res. 18:119-127, 1990). As one approach to identification of sequences which might participate in the linkage, we have mapped sequences derived from the 5' 378 bases of Harvey sarcoma virus (HaSV) RNA which can dimerize in vitro. We found that at least three distinct regions, consisting of nucleotides 37 to 229, 205 to 272, and 271 to 378, can form these dimers. Two of these regions contain nucleotides 205 to 226; computer analysis suggests that this region can form a stem-loop with an inverted repeat in the loop. We propose that this hypothetical structure is involved in dimer formation by these two transcripts. We also compared the thermal stabilities of each of these dimers with that of HaSV viral RNA. Dimers of nucleotides 37 to 229 and 205 to 272 both exhibited melting temperatures near that of viral RNA, while dimers of nucleotides 271 to 378 are quite unstable. We also found that dimers of nucleotides 37 to 378 formed at 37 degrees C are less thermostable than dimers of the same RNA formed at 55 degrees C. It seems possible that bases from all of these regions participate in the dimer linkage present in viral RNA.

Inhibition of human immunodeficiency virus expression by sense transcripts encoding the retroviral leader RNA

Towards gene therapy for the treatment of human immunodeficiency virus type 1 (HIV-1) infections, we tested the potency of several antiviral constructs in transient HIV-1 production assays. Whereas little effect was obtained with antisense- and TAR decoy-constructs, we measured efficient inhibition of HIV-1 mRNA translation and virion production in the presence of HIV-1 leader-containing transcripts. The infectivity of these virions was also reduced by this sense inhibitor RNA. These results suggest that leader-encoded functions, like the dimer-linkage structure, can be used to specifically inhibit HIV expression in trans.

The central globular domain of the nucleocapsid protein of human immunodeficiency virus type 1 is critical for virion structure and infectivity

The nucleocapsid protein NCp7 of human immunodeficiency virus type 1 (HIV-1) is a 72-amino-acid peptide containing two CCHC-type zinc fingers linked by a short basic sequence, 29RAPRKKG35, which is conserved in HIV-1 and simian immunodeficiency virus. The complete three-dimensional structure of NCp7 has been determined by 1H-nuclear magnetic resonance spectroscopy (N. Morellet, H. de Rocquigny, Y. Mely, N. Jullian, H. Demene, M. Ottmann, D. Gerard, J. L. Darlix, M. C. Fournié-Zaluski, and B. P. Roques, J. Mol. Biol. 235:287-301, 1994) and revealed a central globular domain where the two zinc fingers are brought in close proximity by the RAPRKKG linker. To examine the role of this globular structure and more precisely of the RAPRKKG linker in virion structure and infectivity, we generated HIV-1 DNA mutants in the RAPRKK sequence of NCp7 and analyzed the mutant virions produced by transfected cells. Mutations that probably alter the structure of NCp7 structure led to the formation of very poorly infectious virus (A30P) or noninfectious virus (P31L and R32G). In addition, the P31L mutant did not contain detectable amounts of reverse transcriptase and had an immature core morphology, as determined by electron microscopy. On the other hand, mutations changing the basic nature of NCp7 had poor effect. R29S had a wild-type phenotype, and the replacement of 32RKK34 by SSS (S3 mutant) resulted in a decrease by no more than 100-fold of the virus titer. These results clearly show that the RAPRKKG linker contains residues that are critical for virion structure and infectivity.

A 19-nucleotide sequence upstream of the 5' major splice donor is part of the dimerization domain of human immunodeficiency virus 1 genomic RNA

The genome of all retroviruses, including human immunodeficiency virus type 1 (HIV-1), consists of two identical RNAs noncovalently linked near their 5' end. Dimerization of genomic RNA is thought to modulate several steps in the retroviral life cycle, such as recombination, translation, and encapsidation. We report the results of experiments designed to identify the 5' and 3' boundaries of the dimerization domain of the HIV-1 genome: (1) An HIV-1 RNA starting at nucleotide 252 or at other downstream positions (four tested) does not dimerize despite the inclusion of the whole of a previously proposed dimerization domain (nucleotides 295-401); (2) an RNA starting between nucleotides 242 and 249 (five positions tested) dimerizes to a variable extent depending on the starting position; (3) an RNA starting at nucleotide 233 or at other upstream positions (five tested) is fully or > 80% dimeric; (4) an RNA starting at nucleotide 1 but lacking the 233-251 or the 242-251 region is, respectively, fully monomeric or about 50% monomeric; (5) the 343-401 region contains two strings of G's (GGGGG367 and GGG384) that had been postulated to promote genome dimerization through the formation of guanine quartets. We have deleted the 379-401, 358-401, and 343-401 regions from otherwise dimeric RNAs without changing their ability to dimerize. We reach three conclusions: (1) a dimerization signal exists upstream of the major 5' splice donor (nucleotide 290); (2) the previously proposed downstream dimerization domain is insufficient to promote dimerization and has a 3' half that is not necessary to obtain fully dimeric RNAs; (3) the 5' boundary of the HIV-1 dimerization domain is located somewhere between nucleotides 233 and 242, and the 3' boundary is located no farther than at nucleotide 342, making it possible that the 5' and 3' boundaries of the HIV-1 dimerization domain are both located within the leader sequence. We speculate that the 248-270 or 233-285 region forms a hairpin that is the core dimerization domain of HIV-1 RNA.

1H NMR structure and biological studies of the His23-->Cys mutant nucleocapsid protein of HIV-1 indicate that the conformation of the first zinc finger is critical for virus infectivity

The nucleocapsid protein NCp7 of human immunodeficiency virus type 1 (HIV-1), which has key functions in the virus life cycle, possesses two zinc fingers of the CX2CX4HX4C type characterized by three successive loops containing a tetrahedrally coordinated zinc atom. The replacement of any cysteine by a serine in either finger has been shown to result in the production of noninfectious viruses, probably by impairing the biological functions of NCp7. In order to more precisely elucidate the structural role of the zinc finger motif, His23 was replaced by Cys in the proximal finger of the peptide (13-64)NCp7 which retains NCp7 activities in vitro. The peptide Cys23(13-64)NCp7 was synthesized by solid phase and studied by 2D 1H NMR and molecular modeling. The His to Cys modification causes important structural modifications of the N-terminal zinc finger which impair the spatial proximity of the two zinc fingers as shown by the disappearance of several interresidue NOEs. The side chains of Val13, Lys14, Phe16, Thr24, Ala25, Trp37, Gln45, and Met46, which are thought to be involved in nucleic acid recognition, are no longer found clustered in the Cys23(13-64)NCp7 mutant as they are in the wild-type NCp7 structure. In vitro, Cys23(13-64)NCp7 is unable to tightly interact with the viral RNA or replication primer tRNA(Lys,3). The Cys23(NCp7) mutation was introduced into an infectious HIV-1 molecular clone, and virions produced upon DNA transfection into cells were analyzed for their viral protein and RNA compositions as well as for their infectivity. Results show that, while the Cys23(NCp7) mutation does not impair virion production, viruses contain a low amount of degraded viral RNA and are not infectious. These findings suggest that a bona fide conformation of the HIV-1 NCp7 is critical for the packaging of viral RNA, its stability in virions, and virus infectivity.

DNA strand exchange and selective DNA annealing promoted by the human immunodeficiency virus type 1 nucleocapsid protein

Nucleocapsid protein (NC) of human immunodeficiency virus type 1 (HIV-1) was expressed in Escherichia coli and purified. The protein displayed a variety of activities on DNA structure, all reflecting an ability to promote transition between double-helical and single-stranded conformations. We found that, in addition to its previously described ability to accelerate renaturation of complementary DNA strands, the HIV-1 NC protein could substantially lower the melting temperature of duplex DNA and could promote strand exchange between double-stranded and single-stranded DNA molecules. Moreover, in the presence of HIV-1 NC, annealing of a single-stranded DNA molecule to a complementary DNA strand that would yield a more stable double-stranded product was favored over annealing to alternative complementary DNA strands that would form less stable duplex products (selective annealing). NC thus appears to lower the kinetic barrier so that double-strand <==> single-strand equilibrium is rapidly reached to favor the lowest free-energy nucleic acid conformation. This activity of NC may be important for correct folding of viral genomic RNA and may have practical applications.

Evidence that a central domain of nucleocapsid protein is required for RNA packaging in murine leukemia virus

We have analyzed RNA packaging by a series of mutants altered in the nucleocapsid (NC) protein of Moloney murine leukemia virus (Mo-MuLV). We found that mutants lacking residues 8 through 11 or 44 through 60 of NC package Mo-MuLV RNA with virtually the same efficiency as wild-type Mo-MuLV. In contrast, point mutants altered at the conserved cysteines in the cysteine array (residues 26 and 29) and a mutant lacking residues 16 through 23 packaged Mo-MuLV RNA with approximately 1% of the efficiency of wild-type Mo-MuLV. The deficiency in packaged RNA was observed not only in Northern (RNA) analysis but also in an RNA-PCR assay, which would detect degraded as well as intact RNA. One of the cysteine array mutants was also shown to be defective with respect to encapsidation of hygromycin phosphotransferase mRNA containing a Mo-MuLV packaging signal. We suggest that a central region of NC, consisting of the cysteine array and flanking basic residues, is required for RNA packaging in Mo-MuLV.

Efficiency and selectivity of RNA packaging by Rous sarcoma virus Gag deletion mutants

In all retrovirus systems studied, the leader region of the RNA contains a cis-acting sequence called psi that is required for packaging the viral RNA genome. Since the pol and env genes are dispensable for formation of RNA-containing particles, the gag gene product must have an RNA binding domain(s) capable of recognizing psi. To gain information about which portion(s) of Gag is required for RNA packaging in the avian sarcoma and leukemia virus system, we utilized a series of gag deletion mutants that retain the ability to assemble virus-like particles. COS cells were cotransfected with these mutant DNAs plus a tester DNA containing psi, and incorporation of RNA into particles were measured by RNase protection. The efficiency of packaging was determined by normalization of the amount of psi+ RNA to the amount of Gag protein released in virus-like particles. Specificity of packaging was determined by comparisons of psi+ and psi- RNA in particles and in cells. The results indicate that much of the MA domain, much of the p10 domain, half of the CA domain, and the entire PR domain of Gag are unnecessary for efficient packaging. In addition, none of these deleted regions is needed for specific selection of the psi RNA. Deletions within the NC domain, as expected, reduce or eliminate both the efficiency and the specificity of packaging. Among mutants that retain the ability to package, a deletion within the CA domain (which includes the major homology region) is the least efficient. We also examined particles of the well-known packaging mutant SE21Q1b. The data suggest that the random RNA packaging behavior of this mutant is not due to a specific defect but rather is the result of the cumulative effect of many point mutations throughout the gag gene.

Monoclonal antibody-mediated inhibition of RNA binding and annealing activities of HIV type 1 nucleocapsid protein

Retroviral nucleocapsid (NC) proteins are highly basic, with one or two zinc fingers, and are required for virion formation, genomic RNA dimerization and packaging, and replication primer tRNA annealing to the viral RNA. We report here the first characterization of monoclonal antibodies directed against a retroviral nucleocapsid protein and their use to study the structure-function relationships of the nucleocapsid protein NCp7 of HIV-1. Four anti-NCp7 monoclonal antibodies (MAbs) have been generated by using NCp7 of HIV-1. The epitope targets of these MAbs were mapped using ELISA and BIAcore techniques. Whereas three of them are specific for epitopes located in the N and C termini of NCp7, the fourth one appears to be conformation specific. Interestingly, only two of these MAbs, the conformation-specific one and the MAb recognizing an N-terminal epitope are able to inhibit the RNA-binding and annealing activities of NCp7 as well as strong-stop DNA synthesis in vitro. The binding of the two other MAbs onto NCp7 either has no effect or enhances the NCp7-RNA interactions. These MAbs also display a differential recognition of the Gag polyprotein precursor, which makes them useful tools for studying NC protein maturation in the course of virion morphogenesis.

Characterization of human immunodeficiency virus type 1 dimeric RNA from wild-type and protease-defective virions

We have characterized the dimeric genomic RNA in particles of both wild-type and protease (PR)-deficient human immunodeficiency virus type 1 (HIV-1). We found that the dimeric RNA isolated from PR- mutant virions has a lower mobility in nondenaturing gel electrophoresis than that from wild-type virions. It also dissociates into monomers at a lower temperature than the wild-type dimer. Thus, the dimer in PR- particles is in a conformation different from that in wild-type particles. These results are quite similar to recent findings on Moloney murine leukemia virus and suggest that a postassembly, PR-dependent maturation event is a common feature in genomic RNAs of retroviruses. We also measured the thermal stability of the wild-type and PR- dimeric RNAs under different ionic conditions. Both forms of the dimer were stabilized by increasing Na+ concentrations. However, the melting temperatures of the two forms were not significantly affected by the identity of the monovalent cation present in the incubation buffer. This observation is in contrast with recent reports on dimers formed in vitro from short segments of HIV-1 sequence: the latter dimers are specifically stabilized by K+ ions. K+ stabilization of dimers formed in vitro has been taken as evidence for the presence of guanine quartet structures. The results suggest that guanine quartets are not involved in the structure linking full-length, authentic genomic RNA of HIV-1 into a dimeric structure.