Mutations that increase in situ priming also decrease circularization for duck hepatitis B virus.

The process of hepadnavirus reverse transcription involves two template switches during the synthesis of plus-strand DNA. The first involves translocation of the plus-strand primer from its site of generation, the 3' end of minus-strand DNA, to the complementary sequence DR2, located near the 5' end of the minus-strand DNA. Plus strands initiated from DR2 are extended to the 5' end of the minus-strand DNA. At this point, the 3' end of the minus strand becomes the template via the second template switch, a process called circularization. Elongation of circularized plus-strand DNA generates relaxed circular DNA. Although most virions contain relaxed circular DNA, some contain duplex linear DNA. Duplex linear genomes are synthesized when the plus-strand primer is used at the site of its generation, the 3' end of the minus-strand template. This type of synthesis is called in situ priming. Although in situ priming is normally low, in some duck hepatitis B virus mutants this type of priming is elevated. For example, mutations within the 3' end of the minus-strand DNA can lead to increased levels of in situ priming. We report here that these same mutations result in a second defect, a less efficient template switch that circularizes the genome. Although it is not clear how these mutations affect both steps in DNA replication, our findings suggest a commonality in the mechanism of initiation of plus-strand synthesis and the template switch that circularizes the genome.

Changing the site of initiation of plus-strand DNA synthesis inhibits the subsequent template switch during replication of a hepadnavirus.

Unique to hepadnavirus reverse transcription is the process of primer translocation, in which the RNA primer for the initiation of plus-strand DNA synthesis is generated at one site on its template, DR1, and is moved to a new site, DR2. For duck hepatitis B virus (DHBV), DR2 is located within 50 nucleotides of the 5' end of the minus-strand DNA template. When the synthesis of plus-strand DNA proceeds to the 5' terminus of the minus strand, the 3' end of the minus strand becomes the template for DNA synthesis. This switch in templates circularizes the nascent genome and is required for the genesis of the relaxed circular form of the DNA and the mature capsid. Maturation of the capsid is a prerequisite for virus egress. We have analyzed a series of DHBV variants in which plus-strand DNA synthesis was initiated from a new position relative to the 5' end of the template. For these variants, the subsequent circularization was inhibited. We found that when the number of nucleotides between the site of initiation of plus-strand DNA synthesis and the 5' end of its template was restored to 54 nucleotides, circularization was substantially restored. These results mean that the process of circularization is influenced by the earlier steps in DNA replication. This sensitivity is consistent with the notion that this region of the nascent genome is in a dynamic structure that is crucial for successful DNA replication.

cis-Acting sequences in addition to donor and acceptor sites are required for template switching during synthesis of plus-strand DNA for duck hepatitis B virus.

A characteristic of all hepadnaviruses is the relaxed-circular conformation of the DNA genome within an infectious virion. Synthesis of the relaxed-circular genome by reverse transcription requires three template switches. These template switches, as for the template switches or strand transfers of other reverse-transcribing genetic elements, require repeated sequences (the donor and acceptor sites) between which a complementary strand of nucleic acid is transferred. The mechanism for each of the template switches in hepadnaviruses is poorly understood. To determine whether sequences other than the donor and acceptor sites are involved in the template switches of duck hepatitis B virus (DHBV), a series of molecular clones which express viral genomes bearing deletion mutations were analyzed. We found that three regions of the DHBV genome, which are distinct from the donor and acceptor sites, are required for the synthesis of relaxed-circular DNA. One region, located near the 3' end of the minus-strand template, is required for the template switch that circularizes the genome. The other two regions, located in the middle of the genome and near DR2, appear to be required for plus-strand primer translocation. We speculate that these cis-acting sequences may play a role in the organization of the minus-strand DNA template within the capsid particle so that it supports efficient template switching during plus-strand DNA synthesis.

Insertions within epsilon affect synthesis of minus-strand DNA before the template switch for duck hepatitis B virus.

Duck hepatitis B virus (DHBV) is a DNA virus that replicates via reverse transcription of a pregenomic RNA (pgRNA). Synthesis of the first strand of DNA (minus-strand DNA) for DHBV can be divided into two steps: (i) synthesis of the first four nucleotides of minus-strand DNA, which is primed by the viral polymerase (P) protein and copied from the sequence 5'-UUAC-3' within the phylogenetically conserved bulge in the encapsidation signal (epsilon) near the 5' end of pgRNA; and (ii) a template switch of the four-nucleotide minus-strand DNA from epsilon to an acceptor site near the 3' end of pgRNA and synthesis of a complete minus-strand DNA. To understand why only four nucleotides of minus-strand DNA were synthesized before the template switch, we introduced small insertions immediately 5' to the UUAC sequence in epsilon and determined whether these epsilon variants were competent for protein priming and whether minus strands longer than four nucleotides were synthesized. Then we determined, in cell culture, whether the longer minus-strand DNAs were competent to undergo a template switch. Also, we analyzed the structure of the epsilon variants, in solution. We found that the epsilon variants were functional for protein priming and RNA encapsidation and that the insertions were copied into minus-strand DNA. However, two mutant viruses that contained two different three-nucleotide insertions failed to synthesize minus-strand DNA efficiently from the acceptor site, even though seven nucleotides of the donor and acceptor sites were identical. These results suggest that the length and/or sequence of the minus-strand DNA copied from epsilon can be important for an efficient template switch. The RNA structural analysis of the epsilon variants indicated alteration in the position and size of the bulge. Overall, these results are consistent with the notion that the template within epsilon is limited to four nucleotides because the remaining two nucleotides located within the bulge are inaccessible for polymerization.

Sequence requirements of the HIV-1 protease flap region determined by saturation mutagenesis and kinetic analysis of flap mutants.

The retroviral proteases (PRs) have a structural feature called the flap, which consists of a short anti-parallel beta-sheet with a turn. The flap extends over the substrate binding cleft and must be flexible to allow entry and exit of the polypeptide substrates and products. We analyzed the sequence requirements of the amino acids within the flap region (positions 46-56) of the HIV-1 PR. The phenotypes of 131 substitution mutants were determined using a bacterial expression system. Four of the mutant PRs with mutations in different regions of the flap were selected for kinetic analysis. Our phenotypic analysis, considered in the context of published structures of the HIV-1 PR with a bound substrate analogs, shows that: (i) Met-46 and Phe-53 participate in hydrophobic interactions on the solvent-exposed face of the flap; (ii) Ile-47, Ile-54, and Val-56 participate in hydrophobic interactions on the inner face of the flap; (iii) Ile-50 has hydrophobic interactions at the distance of both the delta and gamma carbons; (iv) the three glycine residues in the beta-turn of the flap are virtually intolerant of substitutions. Among these mutant PRs, we have identified changes in both kcat and Km. These results establish the nature of the side chain requirements at each position in the flap and document a role for the flap in both substrate binding and catalysis.

Sequence identity of the terminal redundancies on the minus-strand DNA template is necessary but not sufficient for the template switch during hepadnavirus plus-strand DNA synthesis.

The template for hepadnavirus plus-strand DNA synthesis is a terminally redundant minus-strand DNA. An intramolecular template switch during plus-strand DNA synthesis, which permits plus-strand DNA elongation, has been proposed to be facilitated by this terminal redundancy, which is 7 to 9 nucleotides long. The aim of this study was to determine whether the presence of identical copies of the redundancy on the minus-strand DNA template was necessary and/or sufficient for the template switch and at what position(s) within the redundancy the switch occurs for duck hepatitis B virus. When dinucleotide insertions were placed within the copy of the redundancy at the 3' end of the minus-strand DNA template, novel sequences were copied into plus-strand DNA. The generation of these novel sequences could be explained by complete copying of the redundancy at the 5' end of the minus-strand DNA template followed by a template switch and then extension from a mismatched 3' terminus. In a second set of experiments, it was found that when one copy of the redundancy had either three or five nucleotides replaced the template switch was inhibited. When the identical, albeit mutant, sequences were restored in both copies of the redundancy, template switching was not necessarily restored. Our results indicate that the terminal redundancy on the minus-strand DNA template is necessary but not sufficient for template switching.

Previously unsuspected cis-acting sequences for DNA replication revealed by characterization of a chimeric heron/duck hepatitis B virus.

Heron hepatitis B virus (HHBV) is an avian hepadnavirus that is closely related to duck hepatitis B virus (DHBV). To learn more about the mechanism of hepadnavirus replication, we characterized a clone of HHBV that contains a substitution of DHBV sequence from nucleotide coordinates 403 to 1364. This clone, named HDE1, expresses a chimeric pregenomic RNA, a chimeric polymerase (P) protein, and a core (C) protein with a one-amino-acid substitution at its carboxy terminus. We have shown that HDE1 is defective for minus-strand DNA synthesis, resulting in an overall reduction of viral DNA. HDE1 was also defective for plus-strand DNA synthesis, resulting in aberrant ratios of replication intermediates. Genetic complementation assays indicated that HDE1 replication proteins, C and P, are functional for replication and wild-type HHBV proteins do not rescue either defect. These findings indicate that the HDE1 substitution mutation acts primarily in cis. By restoring nucleotides 403 to 902 to the HHBV sequence, we showed that cis-acting sequences for plus-strand DNA synthesis are located in the 5' half of the HDE1 chimeric region. These data indicate the presence of one or more formerly unrecognized cis-acting sequences for DNA synthesis within the chimeric region (nucleotides 403 to 1364). These cis-acting sequences in the middle of the genome might interact directly or indirectly with known cis elements that are located near the ends of the genome. Our findings suggest that a specific higher-order template structure is involved in the mechanism of hepadnavirus DNA replication.

Mutations within DR2 independently reduce the amount of both minus- and plus-strand DNA synthesized during duck hepatitis B virus replication.

The initial aim of this study was to examine the role of complementarity between the plus-strand primer and the minus-strand DNA template for translocation of the plus-strand primer in hepadnaviral replication. We show that when a 5-nucleotide substitution was placed in either DR1 or DR2, translocation of the primer at a detectable level did not occur. Placing the mutation in both DR1 and DR2 did not restore primer translocation, which indicates that complementarity is not the sole determinant for primer translocation. These mutants, in which primer translocation has been inhibited, have been additionally informative. The mutation in DR1 led to efficient synthesis of plus-strand DNA, albeit primed in situ. In contrast, the mutation in DR2 resulted in a reduction in the amount of plus-strand DNA synthesized per unit of minus-strand DNA. These findings were interpreted as indicating that a mutation at DR2, the primer acceptor site, can inhibit both primer translocation and in situ priming. Lastly, we show that mutations within DR2 can result in a reduction in the synthesis of minus-strand DNA and that this reduction is occurring at an early phase of the process. We speculate that this reduction in the amount of minus-strand DNA synthesized could be due to an inhibition of the template switch during minus-strand DNA synthesis.

Transfer of the minus strand of DNA during hepadnavirus replication is not invariable but prefers a specific location.

The current model for replication of duck hepatitis B virus has reverse transcription initiating and copying a UUAC motif within the encapsidation signal, epsilon, near the 5' end of the RNA template. This results in synthesis of four nucleotides of DNA. This short minus-strand DNA product is then transferred to a complementary position, at DR1, near the 3' end of the RNA template. Elongation of minus-strand DNA then ensues. We have examined the transfer of minus-strand DNA during replication of duck hepatitis B virus in cell culture. The initial aim of this work was to examine the effect of mutations at DR1 on the transfer process. We found that when mutations were introduced into the UUAC motif overlapping DR1, the 5' end of minus-DNA no longer mapped to position 2537 but was shifted two or four nucleotides. Mismatches were predicted to exist at the new sites of elongation. Elongation from nucleotide 2537 could be restored in these mutants by making compensatory changes in the UUAC motif within epsilon. This finding led us to examine limitations in the shifting of the site of transfer. When the UUAC motif in epsilon was changed to six different tetranucleotide motifs surrounding position 2537, transfer of minus-strand DNA shifted predictably, albeit inefficiently. Also, when multiple UUAC motifs were introduced near DR1, the UUAC motif at nucleotide 2537 was used preferentially. Overall, our findings confirm the current minus-strand DNA transfer model and demonstrate a marked preference for the site of the transfer.

A side chain at position 48 of the human immunodeficiency virus type-1 protease flap provides an additional specificity determinant.

Substitution of glycine with glutamic acid at position 48 of the human immunodeficiency virus protease resulted in an enzyme with reduced activity on one of the protease processing sites in the viral Pol polyprotein precursor. Cleavage at this site was restored by a second-site substitution in the substrate replacing an aspartic acid with either glycine or asparagine. These results suggest that the glutamic acid side chain in the mutant protease has an unfavorable charge-charge interaction with this position in the substrate. Cleavage of a processing site in the viral Gag polyprotein precursor with the mutant enzyme was enhanced, and this enhancement was dependent on the presence of an arginine residue in the substrate, again suggesting a charge-charge interaction. The potential for such interactions was confirmed using molecular modeling. The effect of the position 48 substitution was attributed to a 10-fold increase in Km for the processing site in Pol. These results indicate that the addition of a side chain at position 48 can alter the specificity of the HIV-1 protease to substrate in a sequence specific manner and that compensatory changes can be made in the substrate.

Identification of temperature-sensitive mutants of the human immunodeficiency virus type 1 protease through saturation mutagenesis. Amino acid side chain requirements for temperature sensitivity.

Human immunodeficiency virus type 1 encodes a protease whose activity is required for the production of infectious virus. An Escherichia coli expression and processing assay system was used to screen 285 protease mutants for temperature-sensitive activity. Fourteen protease mutants had a temperature-sensitive phenotype, and approximately half resulted from conservative amino acid substitutions. Of the 14 substitutions that conferred a temperature-sensitive phenotype, 11 substitutions occurred at 6 positions that represent 3 pairs of residues in the protease that contact each other in the three-dimensional structure. These mutants assist in pinpointing regions of the protease that are important for enzyme activity and stability.

Sequence-independent RNA cleavages generate the primers for plus strand DNA synthesis in hepatitis B viruses: implications for other reverse transcribing elements.

Reverse transcription of RNA into duplex DNA requires accurate initiation of both minus and plus strand DNA synthesis; this in turn requires the generation of specific primer molecules. We have examined plus strand primer generation in the hepatitis B viruses, small DNA viruses that replicate via reverse transcription. The plus strand primer in these viruses is a short capped RNA derived from the 5' end of the RNA template by cleavage at a specific set of sites. To elucidate the cleavage mechanism we constructed a series of viral mutants bearing alterations in and around the cleavage sites. Our results reveal that the cleavage reaction is sequence-independent and indicate that the cleavage sites are positioned by measurement of the distance from the 5' end of the RNA. Comparison of these findings with what is known about RNase H-mediated primer generation in retroviruses and other retroid elements suggests that, despite many divergent features, some common molecular features are preserved.

L1 gene conversion or same-site transposition.

DNA sequence analysis of the same chromosomal region from two haplotypes of Mus musculus and from the related species M. caroli and M. pahari reveals the presence of long interspersed sequence one (LINES-1, or L1) elements residing at the same nucleotide position in the two most distantly related of the species (M. musculus and M. pahari). The DNA sequence of each of these L1 elements is more similar to that of other L1 elements from its own species than to the other. Thus, the L1 sequence at each of these sites is recent with respect to the divergence of the species. This could be a result of recent gene conversion of L1 elements inherited from a common ancestor or of two recent independent L1 insertion events at the same nucleotide position in the two species. Such specificity of insertion would be quite different from the apparent randomness of other characterized L1 insertion events, such as those in the beta-globin locus. If the recent L1 sequences arose at this site by gene conversion of an ancestral L1 element, then the absence of an L1 element at this location in the M. caroli chromosome examined could arise either from its precise deletion from M. caroli or from the segregation into M. caroli of a polymorphic chromosome present in the ancestral population which was missing this L1 element.

Analysis of retroviral protease cleavage sites reveals two types of cleavage sites and the structural requirements of the P1 amino acid.

Retroviruses encode a protease which cleaves the viral Gag and Gag/Pol protein precursors into mature products. To understand the target sequence specificity of the viral protease, the amino acid sequences from 46 known processing sites from 10 diverse retroviruses were compared. Sequence preference was evident in positions P4 through P3' when compared to flanking sequences. Approximately 80% of all cleavage site sequences could be grouped into two classes based on the sequence composition flanking the scissile bond. The sequences at the amino-terminal cleavage site of the major capsid protein of Gag is always a member of one of the two classes while the carboxyl-terminal cleavage site is of the other class, suggesting a biological role for the two classes. Known processing site sequences proved useful in a motif searching strategy to identify processing sites in retroviral protein sequences, particularly in Gag. In all known cleavage sites, the P1 amino acid is hydrophobic and unbranched at the beta-carbon. The sequence requirements of the P1 position were tested by site-directed mutagenesis of the P1 Phe codon in an HIV-1 Pol cleavage site. Mutations were tested for protease-mediated cleavage of the Pol precursor expressed in Escherichia coli.

cis-acting sequences required for encapsidation of duck hepatitis B virus pregenomic RNA.

Hepadnavirus reverse transcription requires that pregenomic RNA first be selectively packaged into a cytoplasmic core particle. This process presumably requires the presence of specific recognition sequences on the pregenomic RNA. To define the cis-acting sequences required for pregenome encapsidation in the duck hepatitis B virus (DHBV), we assayed the packaging efficiency of a series of pregenomic RNA deletion mutants and hybrid DHBV/lacZ fusion transcripts. The 5' boundary of the packaging signal lies within the precore region, starting approximately 35 nucleotides from the cap site of pregenomic RNA; thus, the DR1 sequence required for proper viral DNA synthesis is not included in this signal. To define the 3' boundary of the encapsidation signal, fusion transcripts bearing foreign (lacZ) sequences fused to DHBV at different sites 3' to the pregenomic RNA start site were examined. A surprisingly large region of the DHBV genome proved to be required for packaging of such chimeras, which are efficiently encapsidated only when they contain the first 1,200 to 1,400 nucleotides of DHBV pregenomic RNA. However, mutant genomes bearing insertions within this region are packaged efficiently, making it likely that the actual recognition elements for encapsidation are smaller discontinuous sequences located within this region.

Mutations affecting hepadnavirus plus-strand DNA synthesis dissociate primer cleavage from translocation and reveal the origin of linear viral DNA.

Hepadnaviruses replicate their circular DNA genomes via reverse transcription of an RNA intermediate. The initial product of reverse transcription, minus-strand DNA, contains two copies of a short direct repeat (DR) sequence, termed DR1 and DR2. Plus-strand DNA synthesis initiates at DR2 on minus-strand DNA, using as a primer a short, DR1-containing oligoribonucleotide derived by cleavage and translocation from the 5' end of pregenomic RNA. To clarify the sequence requirements for plus-strand primer cleavage and translocation, we have constructed mutants of the duck hepatitis B virus bearing base changes in or around the DR1 sequence in the primer. A point mutation at the terminal nucleotide of DR1 has a striking phenotype: normal levels of duplex viral DNA are produced, but nearly all of the DNA is linear rather than circular. Mapping of the 5' end of plus-strand DNA reveals that primer cleavage occurs with normal efficiency and accuracy, but the primer is not translocated to DR2; rather, it is extended in situ to generate duplex linear DNA. Other mutations just 3' to DR1 similarly affect primer translocation, although with differing efficiencies. Linear DNA found in wild-type virus preparations has the same fine structure as the mutant linears described above. These results indicate that (i) plus-strand primer cleavage and translocation are distinct steps that can be dissociated by mutation, (ii) lesions in sequences not included in the primer can severely inhibit primer translocation, and (iii) elongation of such untranslocated primers is responsible for the variable quantities of linear DNA that are found in all hepadnaviral stocks.

Plasmid origin of replication of herpesvirus papio: DNA sequence and enhancer function.

Herpesvirus papio (HVP) is a lymphotropic virus of baboons which is related to Epstein-Barr virus (EBV) and produces latent infection. The nucleotide sequence of the 5,775-base-pair (bp) EcoRI K fragment of HVP, which has previously been shown to confer the ability to replicate autonomously, has been determined. Within this DNA fragment is a region which bears structural and sequence similarity to the ori-P region of EBV. The HVP ori-P region has a 10- by 26-bp tandem array which is related to the 20- by 30-bp tandem array from the EBV ori-P region. In HVP there is an intervening region of 764 bp followed by five partial copies of the 26-bp monomer. Both the EBV and HVP 3' regions have the potential to form dyad structures which, however, differ in arrangement. We also demonstrate that a transcriptional enhancer which requires transactivation by a virus-encoded factor is present in the HVP ori-P.

Cleavage of HIV-1 gag polyprotein synthesized in vitro: sequential cleavage by the viral protease.

The virally encoded protease of human immunodeficiency virus is responsible for the processing of the gag and gag-pol polyprotein precursors to their mature polypeptides. Since correct processing of the viral polypeptides is essential for the production of infectious virus, HIV protease represents a potential target for therapeutic agents that may prove beneficial in the treatment of AIDS. In this study, full-length gag polyprotein has been synthesized in vitro to serve as a substrate for bacterially expressed HIV-1 protease. Expression of the protease in E. coli from the lac promoter was enhanced approximately five-fold by deletion of a potential hairpin loop upstream from the codon determining the amino terminus of mature protease. Extracts of induced cultures of E. coli harboring a protease-containing plasmid served as the source of protease activity. The gag polyprotein synthesized in vitro was cleaved by such lysates, producing fragments corresponding in size to p17 plus p24 and mature p24. Immunoprecipitations with monoclonal antibodies to p17 and p24 polypeptides suggest that initial cleavage of gag polyprotein occurs near the p24-p15 junction. The proteolysis was inhibited by pepstatin with an IC50 of 0.15 mM for cleavage at the p24-p15 junction and 0.02 mM for cleavage at the p17-p24 junction.