The mismatched nucleotides in the 5'-terminal hairpin of minute virus of mice are required for efficient viral DNA replication.

The 5'-terminal sequence in the DNA of the parvovirus minute virus of mice (MVM) is a palindrome. It can form a hairpin, the stem of which is entirely base-paired except for three consecutive unpaired nucleotides which form a bubble. Since this structure is well conserved among different parvoviruses, we examined its importance for viral replication by generating MVM mutants with alterations in this region. A clone of MVMp DNA which contained the entire 3' end and more than half of the 5' palindrome was made. Although it lacked the sequence information to form a wild-type bubble, this DNA was infectious. On transfection into A9 fibroblasts, it gave rise to a virus (MVMs) which had a bubble in its 5' palindrome. The bubble consisted of four mismatched nucleotides in the same location as the unpaired nucleotides of the wild-type palindrome. Apparently, neighboring plasmid sequences were incorporated into the viral DNA, enabling formation of the mismatch. This observation suggested that a bubble is critical for growth of MVM but that its sequence is not. To find out whether MVM lacking a bubble in the 5' palindrome is viable, we made a second clone in which the plasmid sequences incorporated in MVMs were removed. Transfection of this DNA gave rise to a virus (MVMx) in which the nucleotides unpaired in the wild-type hairpin are now fully base-paired. Although MVMx can be propagated, it is defective in comparison with wild-type MVMp; it exhibited about a 50-fold-lower ratio of plaque-forming units to DNA content. In mixed infections, MVMp consistently outgrew the bubbleless MVMx. The rate of accumulation of DNA replication intermediates was lower for MVMx than for the wild-type virus. Quantitative analysis of the 5' termini of replicative form DNA suggested that the ability of MVMx to convert hairpin 5' termini to extended termini is impaired. In contrast, the virus with the altered bubble, MVMs, behaved like the wild-type MVMp in all the assays. We conclude that MVM lacking a bubble in its 5'-terminal DNA hairpin is less infectious than and has a selective disadvantage compared with wild-type MVM. The nucleotide sequence of the bubble is not critical. We provide evidence that the presence of a bubble is necessary for efficient viral DNA replication.     

Specific initiation of replication at the right-end telomere of the closed species of minute virus of mice replicative-form DNA.

We have developed an in vitro system that supports the replication of natural DNA templates of the autonomous parvovirus minute virus of mice (MVM). MVM virion DNA, a single-stranded molecule bracketed by short, terminal, self-complementary sequences, is converted into double-stranded replicative-form (RF) DNA when incubated in mouse A9 fibroblast extract. The 3' end of the newly synthesized complementary strand is ligated to the right-end hairpin of the virion strand, resulting in the formation of a covalently closed RF (cRF) molecule as the major conversion product. cRF DNA is not further replicated in A9 cell extract alone. On addition of purified MVM nonstructural protein NS1 expressed from recombinant baculoviruses or vaccinia viruses, cRF DNA is processed into a right-end (5' end of the virion strand) extended form (5'eRF). This is indicative of NS1-dependent nicking of the right-end hairpin at a distinct position, followed by unfolding of the hairpin and copying of the terminal sequence. In contrast, no resolution of the left-end hairpin can be detected in the presence of NS1. In the course of the right-end nicking reaction, NS1 gets covalently attached to the right-end telomere of the DNA product, as shown by immunoprecipitation with NS1-specific antibodies. The 5'eRF product is the target for additional rounds of NS1-induced nicking and displacement synthesis at the right end, arguing against the requirement of the hairpin structure for recognition of the DNA substrate by NS1. Further processing of the 5'eRF template in vitro leads to the formation of dimeric RF (dRF) DNA in a left-to-left-end configuration, presumably as a result of copying of the whole molecule by displacement synthesis initiated at the right-end telomere. Formation of dRF DNA is highly stimulated by NS1. The experimental results presented in this report support various assumptions of current models of parvovirus DNA replication and provide new insights into the replication functions of the NS1 protein.     

Reverse genetic system for the analysis of parvovirus telomeres reveals interactions between transcription factor binding sites in the hairpin stem

The left-hand or 3'-terminal hairpin of minute virus of mice (MVM) contains sequence elements essential for both viral DNA replication at the left-hand origin (oriL) and for the modulation of the P4 promoter, from which the viral nonstructural gene cassette is transcribed. This hairpin sequence has proven difficult to manipulate in the context of the viral genome. Here we describe a system for generating mutant viruses using synthetic hairpin oligonucleotides and a truncated form of the infectious clone. This allows manipulation of the sequence of the left-hand hairpin and examination of the effects in the context of the viral life cycle. We have confirmed the requirement for a functional parvovirus initiation factor (PIF) binding site and determined that an optimized PIF binding site, with 6 bases between the half-sites, was actually detrimental to viral growth. The distal PIF half-site overlaps a cyclic AMP-responsive element (CRE), which was shown to play an important role in initiating infection, particularly in 324K simian virus 40-transformed human fibroblasts. Interestingly, reducing the spacing of the PIF half-sites, and thus the affinity of the binding site for PIF, increased viral fitness relative to wild type in 324K cells, but not in murine A9 cells. These results indicate that the relative importance of factor binding to the CRE and PIF sites during the establishment of an infection differs markedly between these two host cells and suggest that the suboptimal spacing of PIF half-sites found in wild-type virus represents a necessary reduction in the affinity of the PIF interaction in favor of CRE function.     

Proteins of viral and cellular origin bind to the Aleutian disease virus (ADV) DNA 3'-terminal hairpin: presentation of a scheme for encapsidation of ADV DNA.

We have observed the binding of viral and cellular proteins to the Aleutian disease virus (ADV) 3' terminus of replicative-form DNA. Gel retardation assays showed specific band shifts produced by whole-cell extracts from either ADV-infected or uninfected cells, as well as band reduction produced by ADV capsids. In all cases, binding was confined to the turnaround, T-shaped terminal form; no binding to the extended conformation of replicative-form DNA was detected. This indicates the importance of the T-shaped secondary structure in protein recognition. We have previously reported the binding of a 3'-terminal ADV DNA restriction fragment to the ADV capsid protein VP1 (K. Willwand and O.-R. Kaaden, Virology 166:52-57, 1988). Here we show that the region between nucleotides 14 and 102 on the ADV genome is required for binding. It is suggested that the VP1-DNA interaction mediates the binding of ADV DNA to empty viral capsids and that this is followed by displacement synthesis and packaging of ADV progeny DNA. A scheme for the possible mechanism of this process is presented.     

Use of 2-aminopurine fluorescence to study the role of the beta hairpin in the proofreading pathway catalyzed by the phage T4 and RB69 DNA polymerases

For DNA polymerases to proofread a misincorporated nucleotide, the terminal 3-4 nucleotides of the primer strand must be separated from the template strand before being bound in the exonuclease active center. Genetic and biochemical studies of the bacteriophage T4 DNA polymerase revealed that a prominent beta-hairpin structure in the exonuclease domain is needed to efficiently form the strand-separated exonuclease complexes. We present here further mutational analysis of the loop region of the T4 DNA polymerase beta-hairpin structure, which provides additional evidence that residues in the loop, namely, Y254 and G255, are important for DNA replication fidelity. The mechanism of strand separation was probed in in vitro reactions using the fluorescence of the base analogue 2-aminopurine (2AP) and mutant RB69 DNA polymerases that have modifications to the beta hairpin, to the exonuclease active site, or to both. We propose from these studies that the beta hairpin in the exonuclease domain of the T4 and RB69 DNA polymerases functions to facilitate strand separation, but residues in the exonuclease active center are required to capture the 3' end of the primer strand following strand separation.     

Inhibition of Moloney murine leukemia virus integration using polyamides targeting the long-terminal repeat sequences

The retroviral integrase (IN) carries out the integration of the viral DNA into the host genome. Both IN and the DNA sequences at the viral long-terminal repeat (LTR) are required for the integration function. In this report, a series of minor groove binding hairpin polyamides targeting sequences within terminal inverted repeats of the Moloney murine leukemia virus (M-MuLV) LTR were synthesized, and their effects on integration were analyzed. Using cell-free in vitro integration assays, polyamides targeting the conserved CA dinucleotide with cognate sites closest to the terminal base pairs were effective at blocking 3' processing but not strand transfer. Polyamides which efficiently inhibited 3' processing and strand transfer targeted the LTR sequences through position 9. Polyamides that inhibited integration were effective at nanomolar concentrations and showed subnanomolar affinity for their cognate LTR sites. These studies highlight the role of minor groove interactions within the LTR termini for retroviral integration.     

Moloney murine leukemia virus integration protein produced in yeast binds specifically to viral att sites.

The integration protein (IN) of Moloney murine leukemia virus (MuLV), purified after being produced in yeast cells, has been analyzed for its ability to bind its putative viral substrates, the att sites. An electrophoretic mobility shift assay revealed that the Moloney MuLV IN protein binds synthetic oligonucleotides containing att sequences, with specificity towards its cognate (MuLV) sequences. The terminal 13 base pairs, which are identical at both ends of viral DNA, are sufficient for binding if present at the ends of oligonucleotide duplexes in the same orientation as in linear viral DNA. However, only weak binding was observed when the same sequences were positioned within a substrate in a manner simulating att junctions in circular viral DNA with two long terminal repeats. Binding to att sites in oligonucleotides simulating linear viral DNA was dependent on the presence of the highly conserved CA residues preceding the site for 3' processing (an IN-dependent reaction that removes two nucleotides from the 3' ends of linear viral DNA); mutation of CA to TG abolished binding, and a CA to TA change reduced affinity by at least 20-fold. Removal of either the terminal two base pairs from both ends of the oligonucleotide duplex or the terminal two nucleotides from the 3' ends of each strand did not affect binding. The removal of three 3' terminal nucleotides, however, abolished binding, suggesting an essential role for the A residue immediately upstream of the 3' processing site in the binding reaction. These results help define the sequence requirements for att site recognition by IN, explain the conservation of the subterminal CA dinucleotide, and provide a simple assay for sequence-specific IN activity.     

Molecular characterization of a newly recognized mouse parvovirus.

Mouse parvovirus (MPV), formerly known as orphan parvovirus, is a newly recognized rodent parvovirus distinct from both serotypes of minute virus of mice (MVM). Restriction analysis of the MPV genome indicated that many restriction sites in the capsid region were different from those of MVM, but most sites in the nonstructural (NS) region of the genome were conserved. MPV resembled MVM in genome size, replication intermediates, and NS proteins. Replication intermediates in infected cells were the same for MPV and MVM, including packaging of the 5-kb minus (V) strand. Furthermore, the MPV NS proteins were the same size as and present at the same ratio as the MVM(i) proteins in infected cells. Cloning and sequencing of the MPV genome revealed a genome organization closely resembling that of MVM, with conservation of open reading frames, promoter sequences, and splice sites. The left terminal hairpin was identical to that of MVM(i), but the right terminus was not conserved. Also, the MPV genome was unique in that it contained 1.8 copies of the terminal repeat sequence rather than the 1 or 2 copies found in other parvoviruses. The predicted amino acid sequence of the NS proteins of MPV and MVM(i) were nearly identical. In contrast, the predicted amino acid sequence of the capsid proteins of MPV was different from sequences of other parvoviruses. These results confirm that MPV is a distinct murine parvovirus and account for the antigenic differences between MPV and MVM.     

In vitro resolution of covalently joined AAV chromosome ends

We have developed an assay for a key step in the replication of adeno-associated virus (AAV) DNA. We demonstrate the covalently joined ends of linear AAV DNA can be resolved in vitro to the open duplex configuration. Only extracts prepared from human cells that have been infected with both adenovirus and AAV are capable of carrying out the reaction. The reaction is initiated by a site-specific and strand-specific endonucleolytic cut at a terminal resolution site near the end of the AAV terminal palindrome. During resolution the orientation of the terminal palindrome is inverted, and the 3' viral strand is extended by DNA synthesis. The size of the newly synthesized 3' strand is nearly identical to that found in viral particles. These observations provide direct biochemical evidence for an essential step in the model for AAV DNA replication.     

Two spatially distinct genetic elements constitute a bipartite DNA replication origin in the minute virus of mice genome.

Mutations were introduced into plasmid pMM984, a full-length infectious clone of the fibrotropic strain of minute virus of mice, to identify cis-acting genetic elements required for the excision and replication of the viral genome. The replicative capacity of these mutants was measured directly, using an in vivo transient DNA replication assay following transfection of plasmids into murine A9 cells and primate COS-7 cells. Experiments with subgenomic constructs indicated that both viral termini must be present on the same DNA molecule for replication to occur and that the viral nonstructural protein NS-1 must be provided in trans. The necessary sequences were located within 1,084 and 807 nucleotides of the 3' and 5' ends of the minute virus of mice genome, respectively. The inhibitory effect of deletions within the 206-bp 5'-terminal palindrome demonstrated that these sequences comprise a cis-acting genetic element that is absolutely essential for the excision and replication of viral DNA. The results further indicated a requirement for a stem-plus-arms T structure as well as for the formation of a simple hairpin. In addition, the removal of one copy of a tandemly arranged 65-bp repeat found 94 nucleotides inboard of the 5'-terminal palindrome inhibited viral DNA replication in cis by 10- and just greater than 100-fold in A9 and COS-7 cells, respectively. The latter results define a novel genetic element within the 65-bp repeated sequence, distinct from the terminal palindrome, that is capable of regulating minute virus of mice DNA replication in a species-specific manner.     

Specific interaction of hepatitis C virus protease/helicase NS3 with the 3'-terminal sequences of viral positive- and negative-strand RNA

The hepatitis C virus (HCV)-encoded protease/helicase NS3 is likely to be involved in viral RNA replication. We have expressed and purified recombinant NS3 (protease and helicase domains) and Delta pNS3 (helicase domain only) and examined their abilities to interact with the 3'-terminal sequence of both positive and negative strands of HCV RNA. These regions of RNA were chosen because initiation of RNA synthesis is likely to occur at or near the 3' untranslated region (UTR). The results presented here demonstrate that NS3 (and Delta pNS3) interacts efficiently and specifically with the 3'-terminal sequences of both positive- and negative-strand RNA but not with the corresponding complementary 5'-terminal RNA sequences. The interaction of NS3 with the 3'-terminal negative strand [called 3'(-) UTR(127)] was specific in that only homologous (and not heterologous) RNA competed efficiently in the binding reaction. A predicted stem-loop structure present at the 3' terminus (nucleotides 5 to 20 from the 3' end) of the negative-strand RNA appears to be important for NS3 binding to the negative-strand UTR. Deletion of the stem-loop structure almost totally impaired NS3 (and Delta pNS3) binding. Additional mutagenesis showed that three G-C pairs within the stem were critical for helicase-RNA interaction. The data presented here also suggested that both a double-stranded structure and the 3'-proximal guanosine residues in the stem were important determinants of protein binding. In contrast to the relatively stringent requirement for 3'(-) UTR binding, specific interaction of NS3 (or Delta pNS3) with the 3'-terminal sequences of the positive-strand RNA [3'(+) UTR] appears to require the entire 3'(+) UTR of HCV. Deletion of either the 98-nucleotide 3'-terminal conserved region or the 5' half sequence containing the variable region and the poly(U) and/or poly(UC) stretch significantly impaired RNA-protein interaction. The implication of NS3 binding to the 3'-terminal sequences of viral positive- and negative-strand RNA in viral replication is discussed.     

Drug recognition of a DNA single strand break: nogalamycin intercalation between coaxially stacked hairpins.

Two DNA hairpin motifs (5'-GCGAAGC-3' and 5'-ACGA AGT-3'), both stabilized by a 5'-GAA loop, have been used to design novel intramolecular double hairpin structures (5'-GCGAAGCACGAAGT-3' and 5'-ACGAAGTGCG AAGC-3') in which coaxial stacking of the two hairpin components generates a double-stranded stem region effectively with a single-strand break in the middle of the sequence at either the TG or CA step between unconnected 3' and 5' terminal bases. We have investigated by NMR the conformation and dynamics of the DNA at the strand break site. We show that mutual stacking significantly enhances the stability of each hairpin. Further, the anthracycline antibiotic nogalamycin binds cleanly to the 5'-TG (5'-CA) site formed by the mutually stacked hairpins despite the break in the sugar-phosphate backbone on one strand. The complex resembles the structure of nogalamycin-DNA complexes with the drug bound at 5'-TG sites in intact duplex sequences, with pi-stacking interactions probably the single dominant stabilizing interaction.