Defects in Moloney murine leukemia virus replication caused by a reverse transcriptase mutation modeled on the structure of Escherichia coli RNase H

A flexible split prime editor using truncated reverse transcriptase improves dual-AAV delivery in mouse liver

Prime editor (PE) has tremendous promise for gene therapy. However, it remains a challenge to deliver PE (>6.3 kb) in vivo. Although PE can be split into two fragments and delivered using dual adeno-associated viruses (AAVs), choice of split sites within Cas9-which affects editing efficiency-is limited due to the large size of PE. Furthermore, overexpressing reverse transcriptase in mammalian cells might disrupt translation termination via its RNase H domain. Here, we developed a compact PE without the RNase H domain that showed editing comparable with full-length PE. With compact PE, we used a Cas9 split site (Glu 573) that supported robust editing in cells (up to 93% of full-length PE) and in mouse liver. We then demonstrated that split-cPE573 delivered by dual-AAV8 efficiently mediated a 3-bp TGA insertion in the Pcsk9 gene in mouse liver. Compact PE without the RNase H domain abolished its binding to peptidyl release factor 1 (eRF1) and mitigated the stop codon readthrough effect observed with full-length PE. This study identifies a compact PE with a flexible split design to advance utility of prime editing in vivo.

Structural and Functional Aspects of Foamy Virus Protease-Reverse Transcriptase

Reverse transcription describes the process of the transformation of single-stranded RNA into double-stranded DNA via an RNA/DNA duplex intermediate, and is catalyzed by the viral enzyme reverse transcriptase (RT). This event is a pivotal step in the life cycle of all retroviruses. In contrast to orthoretroviruses, the domain structure of the mature RT of foamy viruses is different, i.e., it harbors the protease (PR) domain at its N-terminus, thus being a PR-RT. This structural feature has consequences on PR activation, since the enzyme is monomeric in solution and retroviral PRs are only active as dimers. This review focuses on the structural and functional aspects of simian and prototype foamy virus reverse transcription and reverse transcriptase, as well as special features of reverse transcription that deviate from orthoretroviral processes, e.g., PR activation.

Inhibition of HIV-1 RNase H Activity by Nucleotide Dimers and Monomers

Nucleotide dimers and monomers were shown to inhibit human immunodeficiency virus type 1 (HIV) RNase H activity. Several effective inhibitors were identified and placed into three general groups based on biochemical characterization of their inhibition, The first group (group A) inhibited HIV RNase H and the closely related feline immunodeficiency virus (FIV) RNase H, but did not inhibit less related retroviral or cellular RNases H or HIV reverse transcriptase (RT). The second group (group B) inhibited the RNase H activity of several retroviruses as well as the reverse transcriptase function of HIV RT. The third group (group C) inhibited RNases H from retroviral and cellular sources but did not inhibit HIV RT. Kinetic analyses of HIV RNase H inhibition were conducted and all three types of inhibitors exhibited a competitive mode of inhibition with regard to substrate. The small nucleotides described here represent the most potent (Ki values from 0.57 to 16 μM) and selective inhibitors of HIV RNase H reported to date. Further structure - function analyses of these molecules may lead to the discovery of unique, potent antiretroviral therapeutics.

Reverse Transcriptase-Associated Ribonuclease H Activity as a Target for Antiviral Chemotherapy

The availability of highly purified recombinant enzymes and model heteropolymeric nucleic acid substrates now allows more precise evaluation of the ribonuclease H (RNase H) activity associated with human immunodeficiency virus (HIV) reverse transcriptase. In addition to degrading the RNA–DNA replicative intermediate, this C-terminal domain of around 130 residues supports highly specialized events that cannot be complemented by host-coded enzymes during retrovirus replication. RNase H activity should therefore be considered a plausible candidate for therapeutic intervention. Events during HIV replication requiring precise RNase H-mediated hydrolysis, the methodologies available to study these events, and their potential for therapeutic intervention are reviewed here.

SiRNA-induced mutation in HIV-1 polypurine tract region and its influence on viral fitness

Converting single-stranded viral RNA into double stranded DNA for integration is an essential step in HIV-1 replication. Initial polymerization of minus-strand DNA is primed from a host derived tRNA, whereas subsequent plus-strand synthesis requires viral primers derived from the 3' and central polypurine tracts (3' and cPPTs). The 5' and 3' termini of these conserved RNA sequence elements are precisely cleaved by RT-associated RNase H to generate specific primers that are used to initiate plus-strand DNA synthesis. In this study, siRNA wad used to produce a replicative HIV-1 variant contained G(-1)A and T(-16)A substitutions within/adjacent to the 3'PPT sequence. Introducing either or both mutations into the 3'PPT region or only the G(-1)A substitution in the cPPT region of NL4-3 produced infectious virus with decreased fitness relative to the wild-type virus. In contrast, introducing the T(-16)A or both mutations into the cPPT rendered the virus(es) incapable of replication, most likely due to the F185L integrase mutation produced by this nucleotide substitution. Finally, the effects of G(-1)A and T(-16)A mutations on cleavage of the 3'PPT were examined using an in vitro RNase H cleavage assay. Substrate containing both mutations was mis-cleaved to a greater extent than either wild-type substrate or substrate containing the T(-16)A mutation alone, which is consistent with the observed effects of the equivalent nucleotide substitutions on the replication fitness of NL4-3 virus. In conclusion, siRNA targeting of the HIV-1 3'PPT region can substantially suppress virus replication, and this selective pressure can be used to generate infectious virus containing mutations within or near the HIV-1 PPT. Moreover, in-depth analysis of the resistance mutations demonstrates that although virus containing a G(-1)A mutation within the 3'PPT is capable of replication, this nucleotide substitution shifts the 3'-terminal cleavage site in the 3'PPT by one nucleotide (nt) and significantly reduces viral fitness.

The solution structure of the prototype foamy virus RNase H domain indicates an important role of the basic loop in substrate binding

Background

The ribonuclease H (RNase H) domains of retroviral reverse transcriptases play an essential role in the replication cycle of retroviruses. During reverse transcription of the viral genomic RNA, an RNA/DNA hybrid is created whose RNA strand needs to be hydrolyzed by the RNase H to enable synthesis of the second DNA strand by the DNA polymerase function of the reverse transcriptase. Here, we report the solution structure of the separately purified RNase H domain from prototype foamy virus (PFV) revealing the so-called C-helix and the adjacent basic loop, which both were suggested to be important in substrate binding and activity.

Results

The solution structure of PFV RNase H shows that it contains a mixed five-stranded β-sheet, which is sandwiched by four α-helices (A-D), including the C-helix, on one side and one α-helix (helix E) on the opposite side. NMR titration experiments demonstrate that upon substrate addition signal changes can be detected predominantly in the basic loop as well as in the C-helix. All these regions are oriented towards the bound substrate. In addition, signal intensities corresponding to residues in the B-helix and the active site decrease, while only minor or no changes of the overall structure of the RNase H are detectable upon substrate binding. Dynamic studies confirm the monomeric state of the RNase H domain. Structure comparisons with HIV-1 RNase H, which lacks the basic protrusion, indicate that the basic loop is relevant for substrate interaction, while the C-helix appears to fulfill mainly structural functions, i.e. positioning the basic loop in the correct orientation for substrate binding.

Conclusions

The structural data of PFV RNase H demonstrate the importance of the basic loop, which contains four positively charged lysines, in substrate binding and the function of the C-helix in positioning of the loop. In the dimeric full length HIV-1 RT, the function of the basic loop is carried out by a different loop, which also harbors basic residues, derived from the connection domain of the p66 subunit. Our results suggest that RNases H which are also active as separate domains might need a functional basic loop for proper substrate binding.

Crystal structures of the reverse transcriptase-associated ribonuclease H domain of xenotropic murine leukemia-virus related virus

The ribonuclease H (RNase H) domain of retroviral reverse transcriptase (RT) plays a critical role in the life cycle by degrading the RNA strands of DNA/RNA hybrids. In addition, RNase H activity is required to precisely remove the RNA primers from nascent (-) and (+) strand DNA. We report here three crystal structures of the RNase H domain of xenotropic murine leukemia virus-related virus (XMRV) RT, namely (i) the previously identified construct from which helix C was deleted, (ii) the intact domain, and (iii) the intact domain complexed with an active site α-hydroxytropolone inhibitor. Enzymatic assays showed that the intact RNase H domain retained catalytic activity, whereas the variant lacking helix C was only marginally active, corroborating the importance of this helix for enzymatic activity. Modeling of the enzyme-substrate complex elucidated the essential role of helix C in binding a DNA/RNA hybrid and its likely mode of recognition. The crystal structure of the RNase H domain complexed with β-thujaplicinol clearly showed that coordination by two divalent cations mediates recognition of the inhibitor.

Insights into the structure and activity of prototype foamy virus RNase H

BACKGROUND

RNase H is an endonuclease that hydrolyzes the RNA strand in RNA/DNA hybrids. Retroviral reverse transcriptases harbor a C-terminal RNase H domain whose activity is essential for viral replication. The RNase H degrades the viral genomic RNA after the first DNA strand is synthesized. Here, we report the biophysical and enzymatic properties of the RNase H domain of prototype foamy virus (PFV) as an independently purified protein. Sequence comparisons with other retroviral RNases H indicated that PFV RNase H harbors a basic protrusion, including a basic loop and the so-called C-helix, which was suggested to be important for activity and substrate binding and is absent in the RNase H domain of human immunodeficiency virus. So far, no structure of a retroviral RNase H containing a C-helix is available.

RESULTS

RNase H activity assays demonstrate that the PFV RNase H domain is active, although its activity is about 200-fold reduced as compared to the full length protease-reverse transcriptase enzyme. Fluorescence equilibrium titrations with an RNA/DNA substrate revealed a KD for the RNase H domain in the low micromolar range which is about 4000-fold higher than that of the full-length protease-reverse transcriptase enzyme. Analysis of the RNase H cleavage pattern using a [32P]-labeled substrate indicates that the independent RNase H domain cleaves the substrate non-specifically. The purified RNase H domain exhibits a well defined three-dimensional structure in solution which is stabilized in the presence of Mg2+ ions.

CONCLUSIONS

Our data demonstrate that the independent PFV RNase H domain is structured and active. The presence of the C-helix in PFV RNase H could be confirmed by assigning the protein backbone and calculating the chemical shift index using NMR spectroscopy.

Ribonuclease H: properties, substrate specificity and roles in retroviral reverse transcription

Retroviral reverse transcriptases possess both a DNA polymerase and an RNase H activity. The linkage with the DNA polymerase activity endows the retroviral RNases H with unique properties not found in the cellular counterparts. In addition to the typical endonuclease activity on a DNA/RNA hybrid, cleavage by the retroviral enzymes is also directed by both DNA 3' recessed and RNA 5' recessed ends, and by certain nucleotide sequence preferences in the vicinity of the cleavage site. This spectrum of specificities enables retroviral RNases H to carry out a series of cleavage reactions during reverse transcription that degrade the viral RNA genome after minus-strand synthesis, precisely generate the primer for the initiation of plus strands, facilitate the initiation of plus-strand synthesis and remove both plus- and minus-strand primers after they have been extended.

Murine leukemia virus reverse transcriptase: structural comparison with HIV-1 reverse transcriptase

Recent X-ray crystal structure determinations of Moloney murine leukemia virus reverse transcriptase (MoMLV RT) have allowed for more accurate structure/function comparisons to HIV-1 RT than were formerly possible. Previous biochemical studies of MoMLV RT in conjunction with knowledge of sequence homologies to HIV-1 RT and overall fold similarities to RTs in general, provided a foundation upon which to build. In addition, numerous crystal structures of the MoMLV RT fingers/palm subdomain had also shed light on one of the critical functions of the enzyme, specifically polymerization. Now in the advent of new structural information, more intricate examination of MoMLV RT in its entirety can be realized, and thus the comparisons with HIV-1 RT may be more critically elucidated. Here, we will review the similarities and differences between MoMLV RT and HIV-1 RT via structural analysis, and propose working models for the MoMLV RT based upon that information.

RNase H activity: structure, specificity, and function in reverse transcription

This review compares the well-studied RNase H activities of human immunodeficiency virus, type 1 (HIV-1) and Moloney murine leukemia virus (MoMLV) reverse transcriptases. The RNase H domains of HIV-1 and MoMLV are structurally very similar, with functions assigned to conserved subregions like the RNase H primer grip and the connection subdomain, as well as to distinct features like the C-helix and loop in MoMLV RNase H. Like cellular RNases H, catalysis by the retroviral enzymes appears to involve a two-metal ion mechanism. Unlike cellular RNases H, the retroviral RNases H display three different modes of cleavage: internal, DNA 3' end-directed, and RNA 5' end-directed. All three modes of cleavage appear to have roles in reverse transcription. Nucleotide sequence is an important determinant of cleavage specificity with both enzymes exhibiting a preference for specific nucleotides at discrete positions flanking an internal cleavage site as well as during tRNA primer removal and plus-strand primer generation. RNA 5' end-directed and DNA 3' end-directed cleavages show similar sequence preferences at the positions closest to a cleavage site. A model for how RNase H selects cleavage sites is presented that incorporates both sequence preferences and the concept of a defined window for allowable cleavage from a recessed end. Finally, the RNase H activity of HIV-1 is considered as a target for anti-virals as well as a participant in drug resistance.

In vitro analysis of the effects of mutations in the G-tract of the human immunodeficiency virus type 1 polypurine tract on RNase H cleavage specificity

The recognition and precise cleavage of the polypurine tract (PPT) of the human immunodeficiency virus type 1 (HIV-1) is an essential step in HIV-1 reverse transcription. The accurate cleavage, and the subsequent removal, of the PPT by the RNase H activity of HIV-1 RT defines the left end of the double-stranded viral DNA genome, the substrate for integration into the host genome. Previous analyses have shown that mutations in the 3'-end (G-tract) of the PPT cause alterations in RNase H cleavage specificity. In particular, mutations at positions 2 and 5 in the G-tract increased the frequency of retention of PPT sequences in the 2-LTR circle junction. To better understand why these mutations affected PPT cleavage in vivo, we analyzed the cleavage of PPT substrates in vitro that contained altered sequences and unusual base substitutions. Our results, herein, confirm that mutations at positions 2 and 5 of the G-tract do significantly alter the cleavage specificity at the PPT/U3 junction, and further suggest that the miscleavages observed in vivo were due to an improper generation of the PPT primer, as opposed to its improper removal. Finally, our results point to the structure of the PPT, rather than the base-specific contacts between the PPT and HIV-1 RT, as the primary determinants of RNase H cleavage specificity at the PPT/U3 junction.

Crystal structure of the moloney murine leukemia virus RNase H domain

A crystallographic study of the Moloney murine leukemia virus (Mo-MLV) RNase H domain was performed to provide information about its structure and mechanism of action. These efforts resulted in the crystallization of a mutant Mo-MLV RNase H lacking the putative helix C (DeltaC). The 1.6-Angstroms resolution structure resembles the known structures of the human immunodeficiency virus type 1 (HIV-1) and Escherichia coli RNase H. The structure revealed the coordination of a magnesium ion within the catalytic core comprised of the highly conserved acidic residues D524, E562, and D583. Surface charge mapping of the Mo-MLV structure revealed a high density of basic charges on one side of the enzyme. Using a model of the Mo-MLV structure superimposed upon a structure of HIV-1 reverse transcriptase bound to an RNA/DNA hybrid substrate, Mo-MLV RNase H secondary structures and individual amino acids were examined for their potential roles in binding substrate. Identified regions included Mo-MLV RNase H beta1-beta2, alphaA, and alphaB and residues from alphaB to alphaD and its following loop. Most of the identified substrate-binding residues corresponded with residues directly binding nucleotides in an RNase H from Bacillus halodurans as observed in a cocrystal structure with RNA/DNA. Finally, superimposition of RNases H of Mo-MLV, E. coli, and HIV-1 revealed that a loop of the HIV-1 connection domain resides within the same region of the Mo-MLV and E. coli C-helix. The HIV-1 connection domain may serve to recognize and bind the RNA/DNA substrate major groove.

Gln(84) of moloney murine leukemia virus reverse transcriptase regulates the incorporation rates of ribonucleotides and deoxyribonucleotides

Moloney murine leukemia virus reverse transcriptase (RT) selectively uses deoxyribonucleotides over ribonucleotides (rNTPs) as substrates. Substitution of F155 with valine (F155V) was previously found to increase the enzyme's affinity for rNTPs, though without affecting the V(max) for catalysis, and thereby conferred to the enzyme significant RNA polymerase activity. We have sought new mutations that might increase the RNA polymerase activity of the F155V mutant. We report here that substitution of Q84 with alanine improved RT-F155V's RNA polymerase activity, but also its DNA polymerase activity. Kinetic analysis and gel-retardation assays suggested that the substitution increased the enzyme's general affinity for the template-primer.

Pervasive genomic recombination of HIV-1 in vivo

Recombinants of preexisting human immunodeficiency virus type 1 (HIV-1) strains are now circulating globally. To increase our understanding of the importance of these recombinants, we assessed recombination within an individual infected from a single source by studying the linkage patterns of the auxiliary genes of HIV-1 subtype B. Maximum-likelihood phylogenetic techniques revealed evidence for recombination from topological incongruence among adjacent genes. Coalescent methods were then used to estimate the in vivo recombination rate. The estimated mean rate of 1.38 x 10(-4) recombination events/adjacent sites/generation is approximately 5.5-fold greater than the reported point mutation rate of 2.5 x 10(-5)/site/generation. Recombination was found to be frequent enough to mask evidence for purifying selection by Tajima's D test. Thus, recombination is a major evolutionary force affecting genetic variation within an HIV-1-infected individual, of the same order of magnitude as point mutational change.

Acceptor RNA cleavage profile supports an invasion mechanism for HIV-1 minus strand transfer

We previously proposed that HIV-1 minus strand transfer occurs by an acceptor invasion-initiated multi-step mechanism. During synthesis of minus strong stop DNA, reverse transcriptase (RT) transiently pauses at the base of TAR before continuing synthesis. Pausing promotes RT-RNase H cleavage of the donor RNA, exposing regions of the cDNA. The acceptor RNA then invades at these locations to interact with the minus strong stop DNA. Whereas primer extension continues on the donor RNA, the cDNA-acceptor hybrid expands by branch migration until transfer of the primer terminus is completed. We present results here showing that the interaction of the acceptor RNA and the cDNA can be determined by examining the time-dependent cleavage of the acceptor RNA by RNase H. Our approach utilizes a combination of RT-RNase H and Escherichia coli RNase H to allow assessment of acceptor-cDNA interactions at high sensitivity. Results show an initial interaction of the acceptor RNA with cDNA at the base of TAR. We observe a time-dependent shift in RNase H susceptibility along the length of the acceptor toward the 5' end, suggesting hybrid propagation from the initial invasion point. Control experiments validate that the RNase H cleavage profile represents the formation and expansion of the acceptor-DNA interaction and that the process is promoted by the nucleocapsid. Observations with this new approach lend additional support to the proposed multistep transfer mechanism.

Effects of mutations in the G tract of the human immunodeficiency virus type 1 polypurine tract on virus replication and RNase H cleavage

The RNase H cleavages that generate and remove the polypurine tract (PPT) primer during retroviral reverse transcription must be specific in order to create a linear viral DNA that is suitable for integration. Lentiviruses contain a highly conserved sequence consisting of six guanine residues at the 3' end of the PPT (hereafter referred to as the G tract). We introduced mutations into the G tract of a human immunodeficiency virus type 1-based vector and determined the effects on the virus titer and RNase H cleavage specificity. Most mutations in the G tract had little or no effect on the virus titer. Mutations at the second and fifth positions of the G tract increased the proportion of two-long-terminal-repeat (2-LTR) circle junctions with one or two nucleotide insertions. The second and fifth positions of the G tract make specific contacts with amino acids in the RNase H domain that are important for RNase H cleavage specificity. These complementary data define protein-nucleic acid interactions that help control the specificity of RNase H cleavage. When the G-tract mutants were analyzed in a viral background that was deficient in integrase, in most cases the proportion of consensus 2-LTR circle junctions increased. However, in the case of a mutant with Ts at the second and fifth positions of the G tract, the proportion of 2-LTR circle junctions containing the one-nucleotide insertion increased, suggesting that linear viral DNAs containing an extra base are substrates for integration. This result is consistent with the idea that the 3' end-processing reactions of retroviral integrases may help to generate defined ends from a heterogenous population of linear viral DNAs.

Characterization of the polymerase and RNase H activities of human foamy virus reverse transcriptase

Foamy virus (FV) replication, while related to that of orthoretroviruses, differs at a number of steps. Several of these differences involve the reverse transcriptase (RT). There appear to be fewer RTs present in FV than in orthoretroviruses; we previously proposed that the polymerase of FV RT was more active than orthoretroviral RTs to compensate for the numerical difference. Here we present further characterization of the RT of FV. The polymerase activity of FV RT was greater than that of human immunodeficiency virus type 1 RT in a variety of assays. We also examined the RNase H activity of FV RT, and we propose that FV RT has a basic loop in the RNase H domain. Although the sequence of the basic loop of FV RT is different from the basic loop of either Moloney leukemia virus RNase H or Escherichia coli RNase H, the FV RT basic loop appears to have a similar function.

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.

Mutations in the 5' end of the human immunodeficiency virus type 1 polypurine tract affect RNase H cleavage specificity and virus titer

The RNase H activity of retroviral reverse transcriptases (RTs) degrades viral genomic RNA after it has been copied into DNA, removes the tRNA used to initiate negative-strand DNA synthesis, and generates and removes the polypurine tract (PPT) primer used to initiate positive-strand DNA synthesis. The cleavages that remove the tRNA and that generate and remove the PPT primer must be specific to generate linear viral DNAs with ends that are appropriate for integration into the host cell genome. The crystal structure of human immunodeficiency virus type 1 (HIV-1) RT in a complex with an RNA/DNA duplex derived from the PPT revealed that the 5' end of the PPT deviates from traditional Watson-Crick base pairing. This unusual structure may play a role in the proper recognition of the PPT by HIV-1 RT. We made substitution mutations in the 5' end of the PPT and determined their effects on virus titer. The results indicated that single and double mutations in the 5' end of the PPT had modest effects on virus replication in a single-cycle assay. More complex mutations had stronger effects on virus titer. Analysis of the two-long-terminal-repeat circle junctions derived from infecting cells with the mutant viruses indicated that the mutations affected RNase H activity, resulting in the retention of PPT sequences on viral DNA. The mutants tested preferentially retained specific segments of the PPT, suggesting an effect on cleavage specificity. These results suggest that structural features of the PPT are important for its recognition and cleavage in vivo.

Mutation of amino acids in the connection domain of human immunodeficiency virus type 1 reverse transcriptase that contact the template-primer affects RNase H activity

The crystal structure of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase in a complex with an RNA-DNA template-primer identified amino acids in the connection domain that make specific contacts with the nucleic acid. We analyzed the effects of mutations in these amino acids by using a one-round HIV-1 vector. Mutations in amino acids in the connection domain generally had small effects on virus titers. To determine whether the mutations affected the level of RNase H activity or the specificity of RNase H cleavage, we used the two-long-terminal-repeat circle junction as a surrogate for the ends of linear viral DNA; specific RNase H cleavages determine the ends of the viral DNA. Several of the mutations in the connection domain affected the frequency of the generation of viral DNAs with aberrant ends. The mutation H361A had the largest effect on the titer and on the generation of DNAs with aberrant ends. H361 contacts the phosphate backbone of the nucleic acid in the same location as amino acid Y501 in the RNase H primer grip. Mutations at Y501 have been shown to decrease the virus titer and affect the specificity of RNase H cleavage. H361A affected the frequency of the generation of linear viral DNAs with aberrant ends, but in general the connection domain mutations had subtle effects on the efficiency of RNase H cleavage. The results of this study suggest that, in addition to its primary role in linking the polymerase and RNase H domains, the connection subdomain has a modest role in binding and positioning the nucleic acid.

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.

Mutations of the RNase H C helix of the Moloney murine leukemia virus reverse transcriptase reveal defects in polypurine tract recognition

Both the RNase H domain of Moloney murine leukemia virus (Mo-MLV) reverse transcriptase (RT) and Escherichia coli RNase H possess a positively charged alpha-helix (C helix) and a loop that are not present in the RNase H domains of human immunodeficiency virus (HIV) RT or avian sarcoma virus RT. Although a mutant Mo-MLV RT lacking the C helix (DeltaC RT) retains DNA polymerase activity on homopolymeric substrates and partial RNase H activity, reverse transcription of the viral RNA genome in vivo is defective. To identify the essential features of the C helix, a panel of Mo-MLV RT mutants was generated. Analyses of these mutant viruses revealed the importance of residues H594, I597, R601, and G602. The mutants were tested for their ability to synthesize viral DNA after acute infections and to form proper 5' and 3' viral DNA ends. The mutant RTs were tested in vitro for exogenous RT activity, minus-strand strong-stop DNA synthesis in endogenous RT reactions, nonspecific RNase H activity, and finally, proper cleavage at the polypurine tract-U3 junction. The R601A mutant was the most defective mutant both in vivo and in vitro and possessed very little RNase H activity. The H594A, I597A, and G602A mutants had significant reductions in RNase H activity and in their rates of viral replication. Many of the mutants formed improper viral DNA ends and were less efficient in PPT-U3 recognition and cleavage in vitro. The data show that the C helix plays a crucial role for overall RNase H cleavage activity. The data also suggest that the C helix may play an important role in polypurine tract recognition and proper formation of the plus-strand DNA's 5' end.

Replication of phenotypically mixed human immunodeficiency virus type 1 virions containing catalytically active and catalytically inactive reverse transcriptase

The amount of excess polymerase and RNase H activity in human immunodeficiency virus type 1 virions was measured by using vectors that undergo a single round of replication. Vectors containing wild-type reverse transcriptase (RT), vectors encoding the D110E mutation to inactivate polymerase, and vectors encoding mutations D443A and E478Q to inactivate RNase H were constructed. 293 cells were cotransfected with different proportions of plasmids encoding these vectors to generate phenotypically mixed virions. The resulting viruses were used to infect human osteosarcoma cells, and the relative infectivity of the viruses was determined by measuring transduction of the murine cell surface marker CD24, which is encoded by the vectors. The results indicated that there is an excess of both polymerase and RNase H activities in virions. Viral replication was reduced to 42% of wild-type levels in virions with where half of the RT molecules were predicted to be catalytically active but dropped to 3% of wild-type levels when 25% of the RT molecules were active. However, reducing RNase H activity had a lesser effect on viral replication. As expected, based on previous work with murine leukemia virus, there was relatively inefficient virus replication when the RNase H and polymerase activities were encoded on separate vectors (D110E plus E478Q and D110E plus D443A). To determine how virus replication failed when polymerase and RNase H activities were reduced, reverse transcription intermediates were measured in vector-infected cells by using quantitative real-time PCR. The results indicated that using the D11OE mutation to reduce the amount of active polymerase reduced the number of reverse transcripts that were initiated and also reduced the amounts of products from the late stages of reverse transcription. If the E478Q mutation was used to reduce RNase H activity, the number of reverse transcripts that were initiated was reduced; there was also a strong effect on minus-strand transfer.

The basic loop of the RNase H domain of MLV RT is important both for RNase H and for polymerase activity

Escherichia coli RNase H has a basic extension that is involved in binding nucleic acid substrates. This basic extension is present in the RNase H of Moloney murine leukemia virus reverse transcriptase (MLV RT), but has been deleted from the RNase H of HIV-1 RT. Previous work showed that removing the basic loop from MLV RT (the mutant is called DeltaC) blocked viral replication; however, DeltaC MLV RT retained RNase H activity in an in situ gel assay. We prepared recombinant DeltaC MLV RT and compared its activity to wild-type MLV RT. The DeltaC mutant is impaired in both polymerase and RNase H activity; the pattern of defects suggests that the basic loop is involved in the binding of MLV RT to a heteropolymeric template-primer.

Substitution of Asp114 or Arg116 in the fingers domain of moloney murine leukemia virus reverse transcriptase affects interactions with the template-primer resulting in decreased processivity

Reverse transcriptase, an essential retroviral DNA polymerase, replicates the single-stranded RNA genome of the retrovirus, producing a double-stranded DNA copy, which is subsequently integrated into the host's genome. Substitution of Ala for either Asp114 or Arg116, two highly conserved residues in the fingers domain of Moloney murine leukemia virus reverse transcriptase, results in enzymes (D114A or R116A) with significant defects in their abilities to processively synthesize DNA using RNA or DNA as a template. D114A and R116A enzymes also bind more weakly to template-primer in the presence of added deoxyribonucleotides, as seen by gel-shift analysis, but retain the ability to strand transfer and accumulate smaller RNase H cleavage products when compared to the wild-type enzyme. In addition, mutant proviruses, including D114A and R116A substitutions in Moloney murine leukemia virus reverse transcriptase, are not viable despite the presence of processed reverse transcriptase in the viral particles. A potential mechanistic role in processive synthesis for D114 and R116 is discussed in the context of our results, related studies on HIV-1 reverse transcriptase, and previous structural studies.

Structure-based moloney murine leukemia virus reverse transcriptase mutants with altered intracellular direct-repeat deletion frequencies

Template switching rates of Moloney murine leukemia virus reverse transcriptase mutants were tested using a retroviral vector-based direct-repeat deletion assay. The reverse transcriptase mutants contained alterations in residues that modeling of substrates into the catalytic core had suggested might affect interactions with primer and/or template strands. As assessed by the frequency of functional lacZ gene generation from vectors in which lacZ was disrupted by insertion of a sequence duplication, the frequency of template switching varied more than threefold among fully replication-competent mutants. Some mutants displayed deletion rates that were lower and others displayed rates that were higher than that of wild-type virus. Replication for the mutants with the most significant alterations in template switching frequencies was similar to that of the wild type. These data suggest that reverse transcriptase template switching rates can be altered significantly without destroying normal replication functions.

Structural determinants of murine leukemia virus reverse transcriptase that affect the frequency of template switching

Retroviral reverse transcriptases (RTs) frequently switch templates within the same RNA or between copackaged viral RNAs to generate mutations and recombination. To identify structural elements of murine leukemia virus RT important for template switching, we developed an in vivo assay in which RT template switching within direct repeats functionally reconstituted the green fluorescent protein gene. We quantified the effect of mutations in the YXDD motif, the deoxynucleoside triphosphate binding site, the thumb domain, and the RNase H domain of RT and hydroxyurea treatment on the frequencies of template switching. Hydroxyurea treatment and some mutations in RT increased the frequency of RT template switching up to fivefold, while all of the mutations tested in the RNase H domain decreased the frequency of template switching by twofold. Based on these results, we propose a dynamic copy choice model in which both the rate of DNA polymerization and the rate of RNA degradation influence the frequency of RT template switching.

Upstream nucleosomes and Rgr1p are required for nucleosomal repression of transcription

The mechanisms of transcription repression and derepression in vivo are not fully understood. We have obtained evidence that begins to clarify the minimum requirements for counteracting nucleosomal repression in vivo. Location of the TATA element near the nucleosome dyad does not block RNA polymerase II transcription in vivo if there is a nucleosome-free region located immediately upstream. However, location of the TATA element similarly within the nucleosome does block transcription if the region upstream of it is nucleosome bound. Histone H4 depletion derepresses transcription in the latter case, supporting the idea that the nucleosomes are responsible for the repression. These results raise the intriguing possibility that the minimum requirement for derepression of transcription in vivo is a nucleosome-free region upstream of the core promoter. Importantly, we find that a C-terminal deletion in RGR1, a component of the mediator/holoenzyme complex and a global repressor, can also derepress transcription.

Replication defect of moloney murine leukemia virus with a mutant reverse transcriptase that can incorporate ribonucleotides and deoxyribonucleotides

Reverse transcriptase (RT) plays a critical role in retrovirus replication, directing the synthesis of a double- stranded DNA copy of the viral RNA genome. We have previously described a mutant RT of the Moloney murine leukemia virus in which F155 was replaced by valine, and we demonstrated that this substitution allowed the enzyme to incorporate ribonucleotides to form RNA while still retaining its normal ability to incorporate deoxyribonucleotides to form DNA. When introduced into the viral genome, this mutation rendered the virus incapable of replication. Characterization of the mutant virus revealed that the enzyme was still active and able to synthesize minus-strand strong stop DNA and some longer products but failed to make full-length minus-strand DNA. We propose that the failure of the enzyme to complete DNA synthesis in vivo resulted from its ability to incorporate ribonucleotides into the products, which served as inhibitors for DNA synthesis. We also tested seven other amino acid residues for their abilities to substitute for F155 in virus replication; of these, only tyrosine could support virus replication. In an attempt to select for second-site suppressor mutations, the F155V mutant was subjected to random mutagenesis and was used as a parent for the isolation of revertant viruses. Two independent revertants were found to have changed the valine residue at position 155 back to the wild- type phenylalanine. These results suggest that an aromatic ring at this position is important for virus replication.

Cloning, expression, and purification of a catalytic fragment of Moloney murine leukemia virus reverse transcriptase: crystallization of nucleic acid complexes

Reverse transcriptase is an essential retroviral enzyme that uses RNA- and DNA-directed DNA polymerase activities as well as an RNaseH activity to synthesize a double-stranded DNA copy of the single-stranded RNA genome. In an effort to obtain high-resolution structural information regarding the polymerase active site of reverse transcriptase, we have pursued studies on a catalytic fragment from Moloney murine leukemia virus reverse transcriptase. DNA encoding the catalytic fragment, defined originally by limited proteolytic digestion, has been cloned, and the protein has been expressed and purified from Escherichia coli. The fragment obtained by limited proteolytic digestion and the bacterially expressed fragnment retain polymerase activity. Crystallization studies involving nucleic acid complexes with a catalytic fragment from both sources are reported, including variables screened to improve crystals and cryocooling. Three crystal forms of catalytic fragment-nucleic acid complexes have been characterized, which all contain at least two protein molecules in the asymmetric unit. As isolated, the catalytic fragment is monomeric. This analysis indicates that the enzyme dimerizes in the presence of nucleic acid.

Interaction of retroviral reverse transcriptase with template-primer duplexes during replication

Conversion of the single-stranded RNA of an invading retrovirus into double-stranded proviral DNA is catalyzed in a multi-step process by a single virus-coded enzyme, reverse transcriptase (RT). Achieving this requires a combination of DNA polymerase abd ribonuclease H (RNase H) activities, which are located at the amino and carboxy terminus of the enzyme, respectively. Moreover, proviral DNA synthesis requires that three structurally-distinct nucleic acid duplexes are accommodated by this enzyme, namely (a) A-form RNA (initiation of minus strand synthesis), non-A, non-B RNA/DNA hybrid (minus strand synthesis and initiation of plus strand synthesis) and B-form duplex DNA (plus strand synthesis). This review summarizes our current understanding of the manner in which retroviral RT interacts with this diverse array of nucleic acid duplexes, exploiting in many cases mutants unable to catalyze a specific event. These studies illustrate that seemingly 'simple' events such as tRNA-primed initiation of minus strand synthesis are considerably more complex, involving intermolecular tRNA-viral RNA interactions outside the primer binding site. Moreover, RNase H activity, generally thought to catalyze non-specific degradation of the RNA-DNA replicative intermediate, is required for highly specialized events including DNA strand transfer and polypurine selection. Finally, a unique structure near the center of HIV proviral DNA, the central termination sequence, serves to halt the replication machinery in a manner analogous to termination of transcription. As these highly specialized events are better understood at the molecular level, they may open new avenues of therapeutic intervention in the continuing effort to stem the progression of HIV infection and AIDS.

Amino acids essential for RNase H activity of hepadnaviruses are also required for efficient elongation of minus-strand viral DNA

The hepadnavirus P gene contains amino acid sequences which share homology with all known RNases H. In this study, we made four mutants in which single amino acids of the duck hepatitis B virus (DHBV) RNase H region were altered. In two of them, amino acids at locations comprising the putative catalytic site were changed, while the remaining mutants had alterations at amino acids conserved among hepadnaviruses. Transfection of these mutant genomes into permissive cells resulted in synthesis of several discrete viral nucleic acid species, ranging in apparent sizes from approximately 500 to 3,000 bp, numbered I, II, III, IV, and V. While the locations of the species were similar in all mutants, the proportions of the species varied among the mutants. Analysis of the nucleic acid species revealed that they were hybrid molecules of RNA and minus-strand DNA, indicating that the RNase H activity was missing or greatly reduced in these mutants. Primer extension experiments showed that the mutant viruses initiated minus-strand viral DNA synthesis normally. The 3' termini of minus-strand DNA in species II, III, and IV were mapped just downstream of nucleotides 1659, 1220, and 721, respectively. Species V contained essentially full-length minus-strand viral DNA. A parallel amino acid change in the putative catalytic site of the HBV RNase H domain resulted in accumulation of low-molecular-weight hybrid molecules consisting of RNA and minus-strand DNA and similar in size and pattern to those seen with DHBV. These studies demonstrate experimentally the involvement of the C-terminal portion of the P gene in RNase H activity in both DHBV and human hepatitis B virus and indicate that the amino acids essential for RNase H activity of hepadnavirus P protein are also important for the efficient elongation of minus-strand viral DNA.

Cystatins in health and disease

Proteolytic enzymes have many physiological functions in plants, bacteria, viruses, protozoa and mammals. They play a role in processes such as food digestion, complement activation or blood coagulation. The action of proteolytic enzymes is biologically controlled by proteinase inhibitors and increasing attention is being paid to the physiological significance of these natural inhibitors in pathological processes. The reason for this growing interest is that uncontrolled proteolysis can lead to irreversible damage e.g. in chronic inflammation or tumor metastasis. This review focusses on the possible role of the cystatins, natural and specific inhibitors of the cysteine proteinases, in pathological processes.

Differential effects of Moloney murine leukemia virus reverse transcriptase mutations on RNase H activity in Mg2+ and Mn2+

We have previously described the in vitro and in vivo characterization of a panel of mutations affecting the RNase H domain of Moloney murine leukemia virus reverse transcriptase (Blain, S. W., and Goff, S.P. (1993) J. Biol. Chem. 268, 23585-23592; Blain, S. W., and Goff, S. P. (1995) J. Virol. 69, 4440-4452). We were intrigued by a discrepancy between in vitro and in vivo RNase H results for two of the mutants. While delta C and delta 5E appeared to have nearly wild-type RNase H activity in vitro, they were unable to degrade their genomic RNA in vivo and thus were effectively RNase H null mutants in this context. In this present report, we describe the differential effects of these mutations on RNase H activity in vitro in the presence of Mg2+ versus Mn2+: mutants delta C and delta 5E were active in the presence of the less biologically relevant Mn2+ and not in the presence of Mg2+. We also describe three mutants with only partial activity in Mg2+. The presence of the different cations can also affect DNA polymerization and processivity of an RNase H-deficient mutant.

Mechanistic implications from the structure of a catalytic fragment of Moloney murine leukemia virus reverse transcriptase

BACKGROUND

Reverse transcriptase (RT) converts the single-stranded RNA genome of a retrovirus into a double-stranded DNA copy for integration into the host genome. This process requires ribonuclease H as well as RNA- and DNA-directed DNA polymerase activities. Although the overall organization of HIV-1 RT is known from previously reported crystal structures, no structure of a complex including a metal ion, which is essential for its catalytic activity, has been reported.

RESULTS

Here we describe the structures at 1.8 Angstrum resolution of a catalytically active fragment of RT from Moloney murine leukemia virus (MMLV) and at 2.6 Angstrum of a complex of this fragment with Mn2+ coordinated in the polymerase active site. On the basis of similarities with HIV-1 RT and rat DNA polymerase beta, we have modeled template/primer and deoxyribonucleoside 5'-triphosphate substrates into the MMLV RT structure.

CONCLUSIONS

Our model, in the context of the disposition of evolutionarily conserved residues seen here at high resolution, provides new insights into the mechanisms of catalysis, fidelity, processivity and discrimination between deoxyribose and ribose nucleotides.

Reversion of a Moloney murine leukemia virus RNase H mutant at a second site restores enzyme function and infectivity

The reverse transcriptase of retroviruses contains an RNase H activity essential for the proper synthesis of the viral DNA copy of the RNA genome. We have previously characterized a number of point mutations altering the RNase domain of the Moloney murine leukemia virus reverse transcriptase (S. W. Blain and S. P. Goff, J. Biol. Chem. 268:23585-23592, 1993). One such mutation, Y586F (a Y-to-F change at position 586), reduced RNase H activity, as assayed by in situ gel analysis, to about 5% of the wild-type level and prevented viral replication. We have now recovered a revertant virus with near-normal infectivity and in vitro enzymatic activity. The revertant contains a single substitution, N613H, distant in the primary sequence of the protein, but modeling with the Escherichia coli RNase H structure suggests that the reverted residue is close in space to the original substituted residue. Examination of the structure permits some suggestions as to how this second-site revertant restores enzyme activity.

Effects on DNA synthesis and translocation caused by mutations in the RNase H domain of Moloney murine leukemia virus reverse transcriptase

To determine the various roles of RNase H in reverse transcription, we generated a panel of mutations in the RNase H domain of Moloney murine leukemia virus reverse transcriptase based on sequence alignments and the crystal structures of Escherichia coli and human immunodeficiency virus type 1 RNases H (S. W. Blain and S. P. Goff, J. Biol. Chem. 268:23585-23592, 1993). These mutations were introduced into a full-length provirus, and the resulting genomes were tested for infectivity by transient transfection assays or after generation of stable producer lines. Several of the mutant viruses replicated normally, some showed significant delays in infectivity, and others were noninfectious. Virions were collected, and the products of the endogenous reverse transcription reaction were examined to determine which steps might be affected by these mutations. Some mutants left their minus-strand strong-stop DNA in RNA-DNA hybrid form, in a manner similar to that of RNase H null mutants. Some mutants showed increased polymerase pausing. Others were impaired in first-strand translocation, independently of their wild-type ability to degrade genomic RNA, suggesting a new role for RNase H in strand transfer. DNA products synthesized in vivo by the wild-type and mutant viruses were also examined. Whereas wild-type virus did not accumulate detectable levels of minus-strand strong-stop DNA, several mutants were blocked in translocation and did accumulate this intermediate. These results suggest that in vivo wild-type virus normally translocates minus-strand strong-stop DNA efficiently.

Defects in primer-template binding, processive DNA synthesis, and RNase H activity associated with chimeric reverse transcriptases having the murine leukemia virus polymerase domain joined to Escherichia coli RNase H

The RNase H domain of murine leukemia virus (MuLV) reverse transcriptase (RT) was replaced with Escherichia coli RNase H, and the effect on RNase H activity and processive DNA synthesis was studied, using RNA-DNA hybrids containing sequences from the MuLV polypurine tract (PPT). Two chimeric RTs, having the entire polymerase domain or all but the last 19 amino acids, were expressed. In both cases, these RTs made multiple cuts in PPT-containing substrates, whereas wild-type cleavages occurred primarily at sites consistent with the distance between the polymerase and RNase H active sites. Primer extension assays performed with the chimeric RTs, an RNase H-minus RT, and wild-type showed that the presence of a wild-type viral RNase H domain facilitates processive DNA synthesis. When wild-type RT was bound to primer-template, two retarded bands could be detected in band-shift assays. In the absence of primer extension, a high proportion of enzyme-bound primer-template was associated with the faster-migrating band, whereas with DNA synthesis, more of the bound radioactivity was in the super-shifted complex. This suggests that the super-shifted complex contains the active form of RT. The mutant RTs were deficient in formation of this complex, but the chimeric RTs were somewhat less defective than the RNase H-minus mutant. Our results demonstrate that in the wild-type enzyme, the RNase H domain is required to stabilize the interaction between RT and primer-template.

Substitution of a highly basic helix/loop sequence into the RNase H domain of human immunodeficiency virus reverse transcriptase restores its Mn(2+)-dependent RNase H activity

Human immunodeficiency virus (HIV) reverse transcriptase (RT) is a multifunctional protein, containing both DNA polymerase and RNase H activity. The RNase H activity of HIV RT catalyzes the hydrolysis of the RNA strand of RNA.DNA hybrids. While the domain that carries out the RNase H activity in HIV RT can be expressed as an independent, folded polypeptide, it is inactive as an RNase H. Here, we report the overexpression and purification of an active, recombinant HIV RNase H domain in which the sequence corresponding to the Escherichia coli RNase H1 basic helix/loop has been substituted for the corresponding sequence of HIV RNase H. The resulting polypeptide (RNH102) has Mn(2+)-dependent RNase H activity and is more stable than the independently expressed wild-type HIV RNase H domain.

Contributions of DNA polymerase subdomains to the RNase H activity of human immunodeficiency virus type 1 reverse transcriptase

Previous studies showed that an isolated human immunodeficiency virus type 1 (HIV-1) RNase H domain expressed as a fusion protein is highly active in Mn2+, but activity was dependent on a hexahistidine tag located at either the carboxyl or amino terminus of the fusion protein (J. Smith and M. Roth, J. Virol. 67:4037-4049, 1993). It was postulated that a histidine tag can somehow provide a function normally associated with the DNA polymerase domain of HIV-1 reverse transcriptase. To determine the contributions of the DNA polymerase subdomains of HIV-1 reverse transcriptase to its RNase H activity, we have characterized the activity of isolated RNase H domains which include either portions of the connection, the entire connection, or both the thumb and connection as N-terminal extensions. Including increasing lengths of these domains at the N terminus of the RNase H resulted in a progressive increase in Mn(2+)-dependent RNase H activity that was independent of a histidine tag. Activity of the isolated RNase H domains was also stimulated by the addition of independently purified polymerase subdomains. Further, this stimulation was shown to be a result of direct physical interactions between the thumb, connection, and RNase H domains. The connection and thumb subdomains were shown to contribute to substrate binding. The fingers and palm subdomains were found to be essential for Mg(2+)-dependent RNase H activity.

RNase H domain mutations affect the interaction between Moloney murine leukemia virus reverse transcriptase and its primer-template

The active sites for the polymerase and nuclease activities of Moloney murine leukemia virus (M-MuLV) reverse transcriptase (RT) reside in separate domains of a single polypeptide. We have studied the effects of RNase H domain mutations on DNA polymerase activity. These mutant RTs displayed decreased processivity of DNA synthesis. We also compared complexes formed between primer-templates and mutant and wild-type reverse transcriptase (RT). Although M-MuLV RT is monomeric in solution, two molecules of RT bound DNA cooperatively, suggesting that M-MuLV RT binds primer-template as a dimer. Some mutant RTs with decreased processivity failed to form the putative dimer.