The effect of mutations in the HIV-1 nucleocapsid protein on strand transfer in cell-free reverse transcription reactions

The N-terminal zinc finger and flanking basic domains represent the minimal region of the human immunodeficiency virus type-1 nucleocapsid protein for targeting chaperone function

The human immunodeficiency virus type-1 (HIV-1) nucleocapsid (NC) protein is a chaperone that facilitates nucleic acid conformational changes to produce the most thermodynamically stable arrangement. The critical role of NC in many steps of the viral life cycle makes it an attractive therapeutic target. The chaperone activity of NC depends on its nucleic acid aggregating ability, duplex destabilizing activity, and rapid on-off binding kinetics. During the minus-strand transfer step of reverse transcription, NC chaperones the annealing of highly structured transactivation response region (TAR) RNA to the complementary TAR DNA. In this work, the role of different functional domains of NC in facilitating 59-nucleotide TAR RNA-DNA annealing was probed by using chemically synthesized peptides derived from full-length (55 amino acids) HIV-1 NC: NC(1-14), NC(15-35), NC(1-28), NC(1-35), NC(29-55), NC(36-55), and NC(11-55). Most of these peptides displayed significantly reduced annealing kinetics, even when present at concentrations much higher than that of wild-type (WT) NC. In addition, these truncated NC constructs generally bind more weakly to single-stranded DNA and are less effective nucleic acid aggregating agents than full-length NC, consistent with the loss of both electrostatic and hydrophobic contacts. However, NC(1-35) displayed annealing kinetics, nucleic acid binding, and aggregation activity that were very similar to those of WT NC. Thus, we conclude that the N-terminal zinc finger, flanked by the N-terminus and linker domains, represents the minimal sequence that is necessary and sufficient for chaperone function in vitro. In addition, covalent continuity of the 35 N-terminal amino acids of NC is critical for full activity. Thus, although the hydrophobic pocket formed by residues proximal to the C-terminal zinc finger has been a major focus of recent anti-NC therapeutic strategies, NC(1-35) represents an alternative target for therapeutics aimed at disrupting NC's chaperone function.

Evidence that creation of invasion sites determines the rate of strand transfer mediated by HIV-1 reverse transcriptase

Strand transfer during reverse transcription can produce genetic recombination in human immunodeficiency virus type 1 (HIV-1) when two genomic RNAs, that are not identical, are co-packaged in the virus. Strand transfer was measured in vitro, in reactions involving primer switching from a donor to acceptor RNA template. The transfer product appeared with much slower kinetics than full-length synthesis on the donor template. The goal of this study was to learn more about the transfer mechanism by defining the steps that limit its rate. We previously proposed transfer to include the steps of acceptor invasion, hybrid propagation, terminus transfer, and re-initiation of synthesis on the acceptor template. Unexpectedly, with our templates increasing acceptor concentration increased the transfer efficiency but had no effect on the rate of transfer. Templates with a short region of homology limiting hybrid propagation exhibited a slow accumulation of transfer products, suggesting that for tested long homology templates hybrid propagation was not rate limiting. Substituting a DNA acceptor and adding Klenow polymerase accelerated re-initiation and extension exclusively on the DNA acceptor. This lead to a small rate increase due to faster extension on the acceptor, suggesting re-initiation of synthesis on the tested RNA acceptors was not rate limiting. A substrate was designed in which the 5' end of the primer was single stranded, and complimentary to the acceptor, i.e. having a pre-made invasion site. With this substrate, increasing concentrations of acceptor increased the rate of transfer. Together these data suggest that RNase H cleavage, and dissociation of RNA fragments creating an invasion site was rate limiting on most tested templates. When an accessible invasion site was present, acceptor interaction at that site influence the rate.

Human immunodeficiency virus type 1 nucleocapsid zinc-finger mutations cause defects in reverse transcription and integration

The nucleocapsid (NC) protein from HIV-1 contains two zinc-fingers, both of which are necessary for virus replication. This is the first in-depth study that presents the effects of nucleocapsid zinc-finger substitutions on the kinetics of reverse transcription and integration. Over a 72-h time-course of infection, the quantities of viral DNA (vDNA) observed with viruses containing either the nucleocapsid His23Cys or His44Cys mutations were significantly lower than those observed in infections with virus containing wild-type NC. In addition, the kinetics of vDNA formation and loss were significantly different from wild-type. The kinetic profiles observed indicated reduced vDNA stability, as well as defects in reverse transcription and integration. Overall, the defect in integration was much more pronounced than the reverse transcription defects. This suggests that the principal reason for the replication defectiveness of these mutant viruses is impairment of integration, and thus demonstrates the critical importance of NC in HIV-1 infection.

Effects of donor and acceptor RNA structures on the mechanism of strand transfer by HIV-1 reverse transcriptase

Template switching during reverse transcription contributes to recombination in human immunodeficiency virus type 1 (HIV-1). Our recent studies suggest that the process can occur through a multi-step mechanism involving RNase H cleavage, acceptor invasion, branch migration, and finally primer terminus transfer. In this study, we analyzed the effects of reverse transcriptase (RT)-pausing, RNase H cleavages and template structure on the transfer process. We designed a series of donor and acceptor template pairs with either minimal pause sites or with pause sites at various locations along the template. Restriction sites within the region of homology allowed efficient mapping of the location of primer terminus transfer. Blocking oligomers were used to probe the acceptor invasion site. Introduction of strong pause sites in the donor increased transfer efficiency. However, the new pauses were not necessarily associated with effective invasion. In this system, the primary invasion occurred at a region of donor cleavage associated with weak pausing. These results together with acceptor structure predictions indicated that a potential invasion site is used only in conjunction with a favorable acceptor structure. Stabilizing acceptor structure at the predicted invasion region lowered the transfer efficiency, supporting this conclusion. Differing from previous studies, terminus transfer occurred at a short distance from the invasion site. Introduction of structure into the acceptor template shifted the location of terminus transfer. Nucleocapsid protein, which can improve cDNA-acceptor interactions, increased transfer efficiency with some shift of terminus transfer closer to the invasion site. Overall results support that the acceptor structure has a major influence on the efficiency and position of the invasion and terminus transfer steps.

Specific Interactions Between HIV-1 Nucleocapsid Protein and the TAR Element

During retroviral reverse transcription, the minus-strand strong-stop DNA (ss-cDNA) is transferred to the 3' end of the genomic RNA and this requires the repeat (R) sequences present at both ends of the genome. In vitro, the human immunodeficiency virus type 1 (HIV-1) R sequence can promote DNA strand transfer when present in ectopic internal positions. Using HIV-1 model systems, the R sequences and nucleocapsid protein (NC) were found to be key determinants of ss-cDNA transfer. To gain insights into specific interactions between HIV-1 NC and RNA and the influence of NC on R folding, we investigated the secondary structures of R in two natural contexts, namely at the 5' or 3' end of RNAs representing the terminal regions of the genome, and in two ectopic internal positions that also support efficient minus-strand transfer. To investigate the roles of NC zinc fingers and flanking basic domains in the NC/RNA interactions, we used NC mutants. Analyses of the viral RNA/NC complexes by chemical and enzymatic probings, and gel retardation assays were performed under conditions allowing ss-cDNA transfer by reverse transcriptase. We report that NC binds the TAR apical loop specifically in the four genetic contexts without changing the folding of the TAR hairpin and R region significantly, and this requires the NC zinc fingers. In addition, we show that efficient annealing of cTAR DNA to the 3' R relies on sequence complementarities between TAR and cTAR terminal loops. These findings suggest that the TAR apical loop in the acceptor RNA is the initiation site for the annealing reaction that is chaperoned by NC during the minus-strand transfer.

Steps of the acceptor invasion mechanism for HIV-1 minus strand strong stop transfer

Minus strand strong stop transfer is obligatory for completion of HIV-1 minus strand synthesis. We previously showed evidence for an acceptor invasion-initiated mechanism for minus strand transfer. In the present study, we examined the major acceptor invasion initiation site using a minus strand transfer system in vitro, containing the 97-nucleotide full-length R region. A series of DNA oligonucleotides complementary to different regions of the cDNA was designed to interfere with transfer. Oligomers covering the region around the base of the TAR hairpin were most effective in inhibiting transfer, suggesting that the hairpin base is a preferred site for acceptor invasion. The strong pausing of reverse transcriptase at the base of the TAR and the concomitant RNase H cleavages 10-19 nucleotides behind the pause site correlated with the location of the invasion site. Oligomers closer to the 5'-end of R also inhibited transfer, though less effectively, presumably by blocking strand exchange and branch migration. We propose that pausing of reverse transcriptase at the base of TAR increases RNase H cleavages, creating gaps for acceptor invasion and transfer initiation. Strand exchange then propagates by branch migration, displacing the fragmented donor RNA, including the fragment at the 5' terminus. The primer terminus switches to the acceptor, completing the transfer. Nucleocapsid (NC) protein stimulated transfer efficiency by 5-7-fold. NC enhanced RNase H cleavages close to the TAR base, creating more effective invasion sites for efficient transfer. Most likely, NC also stimulates transfer by promoting strand exchange invasion and branch migration.

Differing roles of the N- and C-terminal zinc fingers in human immunodeficiency virus nucleocapsid protein-enhanced nucleic acid annealing

The replication process of human immunodeficiency virus requires a number of nucleic acid annealing steps facilitated by the hybridization and helix-destabilizing activities of human immunodeficiency virus nucleocapsid (NC) protein. NC contains two CCHC zinc finger motifs numbered 1 and 2 from the N terminus. The amino acids surrounding the CCHC residues differ between the two zinc fingers. Assays were preformed to investigate the activities of the fingers by determining the effect of mutant and wild-type proteins on annealing of 42-nucleotide RNA and DNA complements. The mutants 1.1 NC and 2.2 NC had duplications of the N- and C-terminal zinc fingers in positions 1 and 2. The mutant 2.1 NC had the native zinc fingers with their positions switched. Annealing assays were completed with unstructured and highly structured oligonucleotide complements. 2.2 NC had a near wild-type level of annealing of unstructured nucleic acids, whereas it was completely unable to stimulate annealing of highly structured nucleic acids. In contrast, 1.1 NC was able to stimulate annealing of both unstructured and structured substrates, but to a lesser degree than the wild-type protein. Results suggest that finger 1 has a greater role in unfolding of strong secondary structures, whereas finger 2 serves an accessory role that leads to a further increase in the rate of annealing.

Mechanism of minus strand strong stop transfer in HIV-1 reverse transcription

Retrovirus minus strand strong stop transfer (minus strand transfer) requires reverse transcriptase-associated RNase H, R sequence homology, and viral nucleocapsid protein. The minus strand transfer mechanism in human immunodeficiency virus-1 was examined in vitro with purified protein and substrates. Blocking donor RNA 5'-end cleavage inhibited transfers when template homology was 19 nucleotides (nt) or less. Cleavage of the donor 5'-end occurred prior to formation of transfer products. This suggests that when template homology is short, transfer occurs through a primer terminus switch-initiated mechanism, which requires cleavage of the donor 5' terminus. On templates with 26-nt and longer homology, transfer occurred before cleavage of the donor 5' terminus. Transfer was unaffected when donor 5'-end cleavages were blocked but was reduced when internal cleavages within the donor were restricted. Based on the overall data, we conclude that in human immunodeficiency virus-1, which contains a 97-nt R sequence, minus strand transfer occurs through an acceptor invasion-initiated mechanism. Transfer is initiated at internal regions of the homologous R sequence without requiring cleavage at the donor 5'-end. The acceptor invades at gaps created by reverse transcriptase-RNase H in the donor-cDNA hybrid. The fragmented donor is eventually strand-displaced by the acceptor, completing the transfer.

Destabilization of the HIV-1 complementary sequence of TAR by the nucleocapsid protein through activation of conformational fluctuations

The nucleocapsid protein NCp7 of HIV-1 possesses nucleic acid chaperone properties that are critical for the two obligatory strand transfer reactions required for the synthesis of a complete proviral DNA by reverse transcriptase. The first DNA strand transfer relies on the destabilization by NCp7 of double-stranded segments of the transactivation response region (TAR) sequence at the 3' end of the genomic RNA and the complementary sequence cTAR at the 3' terminus of minus strong-stop DNA, the early product of reverse transcription. In order to determine the dynamics of NCp7-mediated nucleic acid destabilization, we investigated by time-resolved fluorescence spectroscopy and two photon fluorescence correlation spectroscopy, the interaction of a doubly labeled cTAR sequence with NC(12-55) containing NCp7 CCHC zinc fingers and flanking basic amino acid residues. From the chemical rates and the activation energy associated with the conformational fluctuations observed in the absence of NC, it is concluded that such fluctuations are associated with the opening and closing of the double-stranded terminal segments of cTAR. The destabilizing activity of NC(12-55) occurs mainly through a major increase of the opening rate constant of cTAR. Moreover, NC appears to augment the number of pathways between the open and closed states of cTAR, suggesting that it initiates melting of base-pairs at different locations within the terminal segments of cTAR. This activity of NC on the dynamics of cTAR secondary structure is thought to be critical for the formation of the cTAR-TAR complex, which is essential for the specificity and extent of proviral DNA synthesis by reverse transcriptase.

Human immunodeficiency virus type 1 nucleocapsid zn(2+) fingers are required for efficient reverse transcription, initial integration processes, and protection of newly synthesized viral DNA

Human immunodeficiency virus type 1 (HIV-1) containing mutations in the nucleocapsid (NC) Zn(2+) finger domains have greatly reduced infectivity, even though genome packaging is largely unaffected in certain cases. To examine replication defects, viral DNA (vDNA) was isolated from cells infected with viruses containing His-to-Cys changes in their Zn(2+) fingers (NC(H23C) and NC(H44C)), an integrase mutant (IN(D116N)), a double mutant (NC(H23C)/IN(D116N)), or wild-type HIV-1. In vitro assays have established potential roles for NC in reverse transcription and integration. In vivo results for these processes were obtained by quantitative PCR, cloning of PCR products, and comparison of the quantity and composition of vDNA generated at discrete points during reverse transcription. Quantitative analysis of the reverse transcription intermediates for these species strongly suggests decreased stability of the DNA produced. Both Zn(2+) finger mutants appear to be defective in DNA synthesis, with the minus- and plus-strand transfer processes being affected while interior portions of the vDNA remain more intact. Sequences obtained from PCR amplification and cloning of 2-LTR circle junction fragments revealed that the NC mutants had a phenotype similar to the IN mutant; removal of the terminal CA dinucleotides necessary for integration of the vDNA is disabled by the NC mutations. Thus, the loss of infectivity in these NC mutants in vivo appears to result from defective reverse transcription and integration processes stemming from decreased protection of the full-length vDNA. Finally, these results indicate that the chaperone activity of NC extends from the management of viral RNA through to the full-length vDNA.

Ty5 gag mutations increase retrotransposition and suggest a role for hydrogen bonding in the function of the nucleocapsid zinc finger

The Ty5 retrotransposon of Saccharomyces paradoxus transposes in Saccharomyces cerevisiae at frequencies 1,000-fold lower than do the native Ty1 elements. The low transposition activity of Ty5 could be due to differences in cellular environments between these yeast species or to naturally occurring mutations in Ty5. By screening of a Ty5 mutant library, two single mutants (D252N and Y68C) were each found to increase transposition approximately sixfold. When combined, transposition increased 36-fold, implying that the two mutations act independently. Neither mutation affected Ty5 protein synthesis, processing, cDNA recombination, or target site choice. However, cDNA levels in both single mutants and the double mutant were significantly higher than in the wild type. The D252N mutation resides in the zinc finger of nucleocapsid and increases the potential for hydrogen bonding with nucleic acids. We generated other mutations that increase the hydrogen bonding potential (i.e., D252R and D252K) and found that they similarly increased transposition. This suggests that hydrogen bonding within the zinc finger motif is important for cDNA production and builds upon previous studies implicating basic amino acids flanking the zinc finger as important for zinc finger function. Although NCp zinc fingers differ from the zinc finger motifs of cellular enzymes, the requirement for efficient hydrogen bonding is likely universal.

HIV-1 nucleocapsid protein activates transient melting of least stable parts of the secondary structure of TAR and its complementary sequence

The nucleocapsid protein NCp7 of HIV-1 possesses a nucleic acid chaperone activity that is critical in minus and plus strand transfer during reverse transcription. The minus strand transfer notably relies on the ability of NCp7 to destabilize the stable stem with five contiguous, double-stranded segments of both the TAR sequence at the 3' end of the viral genome and the complementary sequence, cTAR, in minus strong-stop DNA. In order to examine the nature and the extent of NCp7 destabilizing activity, we investigated, by absorbance and fluorescence spectroscopy, the interaction of TAR and cTAR with a (12-55)NCp7 peptide containing the zinc-finger motifs but lacking the ability to aggregate the oligonucleotides. The absorbance changes in the UV band of cTAR show that seven to eight base-pairs, on average, are melted per oligonucleotide at a ratio of one peptide to 7.5 nucleotides. In contrast, the melting of TAR does not exceed an average of one base-pair per oligonucleotide. This may be linked to the greater stability of TAR, since a strong correlation between NCp7 destabilizing effect and oligonucleotide stability was observed. The effect of (12-55)NCp7 on the stem terminus was investigated by using a cTAR molecule doubly labeled at the 3' and 5' ends by a donor/acceptor couple. In the absence of the peptide, about 80 % of the oligonucleotides are in a dark non-fluorescent state, having a close proximity of the two dyes. The remaining 20 % are distributed between three fluorescent species, having either the terminal segment, the two terminal segments or all segments of the stem melted. This is in line with a fraying mechanism wherein the stem terminus fluctuates rapidly between open and closed states. Addition of (12-55)NCp7 shifts the equilibrium toward the open species, suggesting that NC enhances fraying of the stem terminus. Taken together, our data suggest that NCp7 activates the transient opening of base-pairs in the least stable parts of the stem. Also, this activity of NCp7 was found to be dependent on the zinc-finger motifs, since no melting was observed with a fingerless NCp7 peptide.

Mechanisms of retroviral recombination

Recombination is a major source of genetic variability in retroviruses. Each viral particle contains two single-stranded genomic RNAs. Recombination mostly results from a switch in template between these two RNAs during reverse transcription. Here we emphasize the main mechanisms underlying recombination that are emerging from recent advances in biochemical and cell culture techniques. Increasing evidence supporting the involvement of RNA secondary structures now complements the predominant role classically attributed to enzyme pausing during reverse transcription. Finally, the implications of recombination on the dynamics of emergence of genomic aberrations in retroviruses are discussed.

The HIV-1 repeated sequence R as a robust hot-spot for copy-choice recombination

Template switching during reverse transcription is crucial for retroviral replication. While strand transfer on the terminal repeated sequence R is essential to achieve reverse transcription, template switching from internal regions of the genome (copy choice) leads to genetic recombination. We have developed an experimental system to study copy-choice recombination in vitro along the HIV-1 genome. We identify here several genomic regions, including the R sequence, where copy choice occurred at high rates. The frequency of copy choice occurring in a given region of template was strongly influenced by the surrounding sequences, an observation that suggests a pivotal role of the folding of template RNA in the process. The sequence R, instead, constituted an exception to this rule since it was a strong hot-spot for copy choice in the different sequence contexts tested. We suggest therefore that the structure of this region has been optimised during viral evolution to ensure efficient template switching independently from the sequences that might surround it.

Two basic regions of NCp7 are sufficient for conformational conversion of HIV-1 dimerization initiation site from kissing-loop dimer to extended-duplex dimer

Nucleocapsid (NC) protein possesses nucleotide-annealing activities, which are used in various processes in retroviral life cycle. As conserved characters, the NC proteins have one or two zinc fingers of CX(2)CX(4)HX(4)C motif surrounded by basic amino acid sequences. Requirement of the zinc fingers for the annealing activities of NC protein remains controversial. In this study, we focused the requirement in the process of maturation of dimeric viral RNA. Discrimination between immature and mature dimers of synthetic RNA corresponding to the dimerization initiation site of human immunodeficiency virus type 1 (HIV-1) genomic RNA was performed based on their Mg(2+)-dependent stability in gel electrophoreses and on their distinct signal pattern from NMR analysis of imino protons. Chaperoning activity of the HIV-1 NC protein, NCp7, and its fragments for maturation of dimeric RNA was investigated using these experimental systems. We found that the two basic regions flanking the N-terminal zinc finger of NCp7, which are connected by two glycine residues instead of the zinc finger, were sufficient, although about 10 times the amounts of peptide were needed in comparison with intact NCp7. Further, it was found that the amount of basic residues rather than the amino acid sequence itself is important for the activity. The zinc fingers may involve the binding affinity and/or such a possible specific binding of NCp7 to dimerization initiation site dimer that leads to the maturation reaction.

Determination of the pK(a) of the four Zn2+-coordinating residues of the distal finger motif of the HIV-1 nucleocapsid protein: consequences on the binding of Zn2+

The nucleocapsid protein NCp7 of human immunodeficiency virus type 1 is characterized by two highly conserved CCHC motifs that bind Zn2+ strongly. To elucidate the striking pH-dependence of the apparent Zn2+-binding constants of these motifs further, we investigated, using 1H NMR, potentiometry and fluorescence spectroscopy, the acid-base properties of the four Zn2+-coordinating residues of (35-50)NCp7, a peptide corresponding to the distal finger motif of NCp7. With the exception of the H(beta2) proton of Cys39, the pH-dependence of the H(beta) proton resonances of the three Cys residues and, the H(delta) and H(epsilon) resonances of His44 in the apopeptide could be fitted adequately with a single pK(a). This suggests that the protonating groups are non-interacting, a feature that was confirmed by a potentiometric titration. The pK(a) of His44, Cys36, Cys39, and Cys49 in the apopeptide were found to be 6.4, 8.0, 8.8 and 9.3, respectively. Accordingly, the deprotonation is almost sequential and may thus induce a sequential binding of Zn2+ to the four coordinating residues. The high pK(a) of Cys49 is probably related to the negative charge of the neighboring Asp48. Such a high pK(a) may be a general feature in nucleocapsid proteins (NCs), since an acidic residue generally occupies the (i-1) position of the C-terminal Cys residue of single-finger NCs and distal finger motifs in two-finger NCs. Molecular dynamics simulation suggested the formation of a hydrogen bonded network that weakly structured the Cys36-Cys39 segment in the apopeptide. This network depends on the protonation state of Cys36 and may thus explain the biphasic behavior of the pH-dependence of the Cys39 H(beta2) resonance. Finally, the pK(a) values were used to build up a model describing the coordination of Zn2+ to (35-50)NCp7 at equilibrium. It appears that each protonation step of the coordination complex decreases the Zn2+-binding constant by about four orders of magnitude and that a significant dissociation of Zn2+ from the holopeptide can be achieved in acidic cell compartments.

Utilization of nonviral sequences for minus-strand DNA transfer and gene reconstitution during retroviral replication

Minus-strand DNA transfer, an essential step in retroviral reverse transcription, is mediated by the two repeat (R) regions in the viral genome. It is unclear whether R simply serves as a homologous sequence to mediate the strand transfer or contains specific sequences to promote strand transfer. To test the hypothesis that the molecular mechanism by which R mediates strand transfer is based on homology rather than specific sequences, we examined whether nonviral sequences can be used to facilitate minus-strand DNA transfer. The green fluorescent protein (GFP) gene was divided into GF and FP fragments, containing the 5' and 3' portions of GFP, respectively, with an overlapping F fragment (85 bp). FP and GF were inserted into the 5' and 3' long terminal repeats, respectively, of a murine leukemia virus-based vector. Utilization of the F fragment to mediate minus-strand DNA transfer should reconstitute GFP during reverse transcription. Flow cytometry analyses demonstrated that GFP was expressed in 73 to 92% of the infected cells, depending on the structure of the viral construct. This indicated that GFP was reconstituted at a high frequency; molecular characterization further confirmed the accurate reconstitution of GFP. These data indicated that nonviral sequences could be used to efficiently mediate minus-strand DNA transfer. Therefore, placement and homology, not specific sequence context, are the important elements in R for minus-strand DNA transfer. In addition, these experiments demonstrate that minus-strand DNA transfer can be used to efficiently reconstitute genes for gene therapy applications.

Zinc finger structures in the human immunodeficiency virus type 1 nucleocapsid protein facilitate efficient minus- and plus-strand transfer

The nucleocapsid protein (NC) of human immunodeficiency virus type 1 (HIV-1) has two zinc fingers, each containing the invariant metal ion binding residues CCHC. Recent reports indicate that mutations in the CCHC motifs are deleterious for reverse transcription in vivo. To identify reverse transcriptase (RT) reactions affected by such changes, we have probed zinc finger functions in NC-dependent RT-catalyzed HIV-1 minus- and plus-strand transfer model systems. Our approach was to examine the activities of wild-type NC and a mutant in which all six cysteine residues were replaced by serine (SSHS NC); this mutation severely disrupts zinc coordination. We find that the zinc fingers contribute to the role of NC in complete tRNA primer removal from minus-strand DNA during plus-strand transfer. Annealing of the primer binding site sequences in plus-strand strong-stop DNA [(+) SSDNA] to its complement in minus-strand acceptor DNA is not dependent on NC zinc fingers. In contrast, the rate of annealing of the complementary R regions in (-) SSDNA and 3' viral RNA during minus-strand transfer is approximately eightfold lower when SSHS NC is used in place of wild-type NC. Moreover, unlike wild-type NC, SSHS NC has only a small stimulatory effect on minus-strand transfer and is essentially unable to block TAR-induced self-priming from (-) SSDNA. Our results strongly suggest that NC zinc finger structures are needed to unfold highly structured RNA and DNA strand transfer intermediates. Thus, it appears that in these cases, zinc finger interactions are important components of NC nucleic acid chaperone activity.