Structural features in the HIV-1 repeat region facilitate strand transfer during reverse transcription.

Two obligatory DNA strand transfers take place during reverse transcription of a retroviral RNA genome. The first strand transfer is facilitated by terminal repeat (R) elements in the viral genome. This strand-transfer reaction depends on base pairing between the cDNA of the 5'R and the 3'R. There is accumulating evidence that retroviral R regions contain features other than sequence complementarity that stimulate this critical nucleic acid hybridization step. The R region of the human immunodeficiency virus type 1 (HIV-1) is relatively extended (97 nt) and encodes two well-conserved stem-loop structures, the TAR and poly(A) hairpins. The role of these motifs was studied in an in vitro strand-transfer assay with two separate templates, the 5'R donor and the 3'R acceptor, and mutants thereof. The results indicate that the upper part of the TAR hairpin structure in the 5'R donor is critical for efficient strand transfer. This seems to pose a paradox, as the 5'R template is degraded by RNase H before strand transfer occurs. We propose that it is not the RNA hairpin motif in the 5'R donor, but rather the antisense motif in the ssDNA copy, which can also fold a hairpin structure, that is critical for strand transfer. Mutation of the loop sequence in the TAR hairpin of the donor RNA, which is copied in the loop of the cDNA hairpin, reduces the transfer efficiency more than fivefold. It is proposed that the natural strand-transfer reaction is enhanced by interaction of the anti-TAR ssDNA hairpin with the TAR hairpin in the 3'R acceptor. Base pairing can occur between the complementary loops ("loop-loop kissing"), and strand transfer is completed by the subsequent formation of an extended RNA-cDNA duplex.

The effect of template RNA structure on elongation by HIV-1 reverse transcriptase.

Reverse transcription of the RNA genome of retroviruses has to proceed through some highly structured regions of the template. The RNA genome of the human immunodeficiency virus type 1 (HIV-1) contains two hairpin structures within the repeat (R) region at the 5' end of the viral RNA (Fig. 1Fig. 1Template RNA structure of the HIV-1 R region and the position of reverse transcription pause sites. The HIV-1 R region (nucleotides +1/97) encodes two stable RNA structures, the TAR and polyA hairpins [5]. The latter hairpin contains the AAUAAA hexamer motif (marked by a box) that is involved in polyadenylation. The lower panel shows the predicted structures of the wild-type and two mutant forms of the polyA hairpin that were used in this study. Nucleotide substitutions are boxed, deletions are indicated by black triangle. The thermodynamic stability (free energy or DeltaG, in kcal/mol) was calculated according to the Zucker algorithm [71]. The TAR hairpin has a DeltaG of -24.8 kcal/mol. Minus-strand DNA synthesis on these templates was initiated by a DNA primer annealed to the downstream PBS. The position of reverse transcription pause sites observed in this study are summarized. All numbers refer to nucleotide positions on the wild-type HIV-1 transcript. Filled arrows represent stops observed on the wild-type template, and open arrows mark the pause sites that are specific for the structured A-mutant template. The sizes of the arrows correspond to the relative frequency of pausing. Little pausing was observed on the B-mutant template with the destabilized polyA hairpin.). These structures, the TAR and polyA hairpins, fulfil important functions in the viral life cycle. We analyzed the in vitro elongation properties of the HIV-1 reverse transcriptase (RT) enzyme on the wild-type RNA template and mutants thereof with either a stabilized or a destabilized polyA hairpin. Stable RNA structure was found to interfere with efficient elongation of the RT enzyme, as judged by the appearance of pause cDNA products. A direct relation was measured between the stability of template RNA structure and the extent of RT pausing. However, the position of structure-induced pause sites is rather diverse, with significant stops at a position approximately 6 nt ahead of the basepaired stem of the TAR and polyA hairpins. This suggests that the RT enzyme is stalled when its most forward domain contacts the RNA duplex. Addition of the viral nucleocapsid protein (NC) to the in vitro assay was found to overcome such structure-induced RT stops. These results indicate that the RT polymerase has problems penetrating regions of the template with stable RNA structure. This effect was more pronounced at high Mg2+ concentrations, which is known to stabilize RNA secondary structure. Such a structure-induced defect was not apparent in reverse transcription assays performed in virus-infected cells, which is either caused by the NC protein or other components of the virion particle. Thus, retroviruses can use relatively stable RNA structures to control different steps in the viral life cycle without interfering with the process of reverse transcription.

The ability of the HIV-1 AAUAAA signal to bind polyadenylation factors is controlled by local RNA structure.

The 5' and 3' ends of HIV-1 transcripts are identical in sequence. This repeat region (R) folds a stem-loop structure that is termed the poly(A) hairpin because it contains polyadenylation or poly(A) signals: the AAUAAA hexamer motif, the cleavage site and part of the GU-rich downstream element. Obviously, HIV-1 gene expression necessitates differential regulation of the two poly(A) sites. Previous transfection experiments indicated that the wild-type poly(A) hairpin is slightly inhibitory to the process of polyadenylation, and further stabilization of the hairpin inhibited polyadenylation completely. In this study, we tested wild-type and mutant transcripts with poly(A) hairpin structures of differing thermodynamic stabilities for the in vitro binding of polyadenylation factors. Mutant transcripts with a destabilized hairpin efficiently bound the polyadenylation factors, which were provided either as purified proteins or as nuclear extract. The RNA mutant with a stabilized hairpin did not form this 'poly(A) complex'. Additional mutations that repair the stability of this hairpin restored the binding capacity. Thus, an inverse correlation was measured between the stability of the poly(A) hairpin and its ability to interact with polyadenylation factors. The wild-type HIV-1 transcript bound the polyadenylation factors suboptimally, but full activity was obtained in the presence of the USE enhancer element that is uniquely present upstream of the 3' poly(A) site. We also found that sequences of the HIV-1 leader, which are uniquely present downstream of the 5' poly(A) site, inhibit formation of the poly(A) complex. This inhibition could not be ascribed to a specific leader sequence, as we measured a gradual loss of complex formation with increasing leader length. We will discuss the regulatory role of RNA structure and the repressive effect of leader sequences in the context of differential HIV-1 polyadenylation.

Inhibition of polyadenylation by stable RNA secondary structure.

The presence of a polyadenylation signal in the repeat (R) region of the HIV-1 genome, which is located at both the 5' and 3' ends of the viral transcripts, requires differential regulation of polyadenylation. The HIV-1 poly(A) site can fold in a stable stem-loop structure that is well-conserved among different human and simian immunodeficiency viruses. In this study, we tested the effect of this hairpin on polyadenylation by introducing mutations that either stabilize or destabilize the RNA structure. The HIV-1 sequences were inserted into the pSV2CAT reporter plasmid upstream of the SV40 early poly(A) site. These constructs were transfected into COS cells and transcripts were analyzed for the usage of the HIV-1 versus SV40 poly(A) site. The wild-type HIV-1 poly(A) site was used efficiently in this context and destabilization of the poly(A) hairpin did not affect the polyadenylation efficiency. In contrast, further stabilization of the hairpin severely inhibited HIV-1 polyadenylation. Additional mutations that repair the thermodynamic stability of this mutant hairpin restored the polyadenylation activity. These results indicate that the mechanism of polyadenylation can be repressed by stable RNA structure encompassing the poly(A) signal. Experiments performed at reduced temperatures also suggest an inverse correlation between the stability of the RNA structure and the efficiency of polyadenylation.

A conserved hairpin motif in the R-U5 region of the human immunodeficiency virus type 1 RNA genome is essential for replication.

The untranslated leader region of the human immunodeficiency virus (HIV) RNA genome contains multiple hairpin motifs. The repeat region of the leader, which is reiterated at the 3' end of the RNA molecule, encodes the well-known TAR hairpin and a second hairpin structure with the polyadenylation signal AAUAAA in the single-stranded loop [the poly(A) hairpin]. The fact that this poly(A) stem-loop structure and its thermodynamic stability are well conserved among HIV and simian immunodeficiency virus isolates, despite considerable divergence in sequence, suggests a biological function for this RNA motif in viral replication. Consistent with this idea, we demonstrate that mutations that alter the stability of the stem region or delete the upper part of the hairpin do severely inhibit replication of HIV type 1. Whereas destabilizing mutations in either the left- or right-hand side of the base-paired stem interfere with virus replication, the double mutant, which allows the formation of new base pairs, replicates more rapidly than the two individual virus mutants. Upon prolonged culturing of viruses with an altered hairpin stability, revertant viruses were obtained with additional mutations that restore the thermodynamic stability of the poly(A) hairpin. Transient transfection experiments demonstrated that transcription of the proviral genomes, translation of the viral mRNAs, and reverse transcription of the genomic RNAs are not affected by mutation of the 5' poly(A) hairpin. We show that the genomic RNA content of the virions is reduced by destabilization of this poly(A) hairpin but not by stabilization or truncation of this structure. These results suggest that the formation of the poly(A) hairpin structure at the 5' end of the genomic RNA molecule is necessary for packaging of viral genomes into virions and/or stability of the virion RNA.