Rotavirus RNA replication requires a single-stranded 3' end for efficient minus-strand synthesis

The segmented double-stranded (ds) RNA genome of the rotaviruses is replicated asymmetrically, with viral mRNA serving as the template for the synthesis of minus-strand RNA. Previous studies with cell-free replication systems have shown that the highly conserved termini of rotavirus gene 8 and 9 mRNAs contain cis-acting signals that promote the synthesis of dsRNA. Based on the location of the cis-acting signals and computer modeling of their secondary structure, the ends of the gene 8 or 9 mRNAs are proposed to interact in cis to form a modified panhandle structure that promotes the synthesis of dsRNA. In this structure, the last 11 to 12 nucleotides of the RNA, including the cis-acting signal that is essential for RNA replication, extend as a single-stranded tail from the panhandled region, and the 5' untranslated region folds to form a stem-loop motif. To understand the importance of the predicted secondary structure in minus-strand synthesis, mutations were introduced into viral RNAs which affected the 3' tail and the 5' stem-loop. Analysis of the RNAs with a cell-free replication system showed that, in contrast to mutations which altered the structure of the 5' stem-loop, mutations which caused complete or near-complete complementarity between the 5' end and the 3' tail significantly inhibited (>/=10-fold) minus-strand synthesis. Likewise, incubation of wild-type RNAs with oligonucleotides which were complementary to the 3' tail inhibited replication. Despite their replication-defective phenotype, mutant RNAs with complementary 5' and 3' termini were shown to competitively interfere with the replication of wild-type mRNA and to bind the viral RNA polymerase VP1 as efficiently as wild-type RNA. These results indicate that the single-strand nature of the 3' end of rotavirus mRNA is essential for efficient dsRNA synthesis and that the specific binding of the RNA polymerase to the mRNA template is required but not sufficient for the synthesis of minus-strand RNA.     

Preservation of the alveolar ridge at implant sites

The cohesive termini including the cos region (altogether 414 bp) of the DNA of the temperate coliphage N15 are sequenced. The termini are complementary 12-nucleotide single-stranded 5'-extended DNAs. The sequence of the left terminus is 5'-GGGCGGCGTCCG-3', that of the right 5'CGGACGCCGCCC-3'. Ten nucleotides of the N15 termini are identical to those of phage lambda. The N15 and lambda sequences are notably homologous only within the 50 bp region from the left and right ends. Phage N15 has a region with the nucleotide sequence identical to the R4 site of phage lambda, presumably reacting with terminase. This region is situated in the same site with regard to the cohesive sequence as in phage lambda. The cos region of N15 has no sequences similar to R1, R2, and R3 of lambda. N15 has a sequence similar to IHF of phage lambda, but in N15 this sequence is located near the right but not left (as in phage lambda) terminus. Computer analysis revealed palindromes and repeats within 450 bp of N15, including the cohesive termini.     

Structure of the ColE1 DNA molecule before segregation to daughter molecules

The segregation of daughter DNA molecules at the end stage of replication of plasmid ColE1 was examined. When circular ColE1 DNA replicates in a cell extract at a high KCl concentration (140 mM), a unique class of molecules accumulates. When the molecule is cleaved by a restriction enzyme that cuts the ColE1 DNA at a single site, an X-shaped molecule in which two linear components are held together around the origin of DNA replication is made. For a large fraction of these molecules, the 5' end of the leading strand remains at the origin and the 3' end of the strand is about 30 nucleotides upstream of the origin. The 3' end of the lagging strand is located at the terH site (17 nucleotides upstream of the origin) and the 5' end of the strand is a few hundred nucleotides upstream of the terH site. Thus the parental strands of the molecule intertwine with each other only once. When the KCl concentration is lowered to 70 mM, practically all of these molecules are converted to daughter circular monomers or to catenanes consisting of two singly interlocked circular units.     

Functional features of an ssi signal of plasmid pGKV21 in Escherichia coli

A single-strand initiation (ssi) signal was detected on the Lactococcus lactis plasmid pGKV21 containing the replicon of pWV01 by its ability to complement the poor growth of an M13 phage derivative (M13 delta lac182) lacking the complementary-strand origin in Escherichia coli. This ssi signal was situated at the 229-nucleotide (nt) DdeI-DraI fragment and located within the 109 nt upstream of the nick site of the putative plus origin. SSI activity is orientation specific with respect to the direction of replication. We constructed an ssi signal-deleted plasmid and then examined the effects of the ssi signal on the conversion of the single-stranded replication intermediate to double-stranded plasmid DNA in E. coli. The plasmid lacking an ssi signal accumulated much more plasmid single-stranded DNA than the wild-type plasmid did. Moreover, deletion of this region caused a great reduction in plasmid copy number or plasmid maintenance. These results suggest that in E. coli, this ssi signal directs its lagging-strand synthesis as a minus origin of plasmid pGKV21. Primer RNA synthesis in vitro suggests that E. coli RNA polymerase directly recognizes the 229-nt ssi signal and synthesizes primer RNA dependent on the presence of E. coli single-stranded DNA binding (SSB) protein. This region contains two stem-loop structures, stem-loop I and stem-loop II. Deletion of stem-loop I portion results in loss of priming activity by E. coli RNA polymerase, suggesting that stem-loop I portion is essential for priming by E. coli RNA polymerase on the SSB-coated single-stranded DNA template.     

Discrete start sites for DNA synthesis in the yeast ARS1 origin

Sites of DNA synthesis initiation have been detected at the nucleotide level in a yeast origin of bidirectional replication with the use of replication initiation point mapping. The ARS1 origin of Saccharomyces cerevisiae showed a transition from discontinuous to continuous DNA synthesis in an 18-base pair region (nucleotides 828 to 845) from within element B1 toward B2, adjacent to the binding site for the origin recognition complex, the putative initiator protein.     

Regulation of RNA synthesis by the genomic termini of vesicular stomatitis virus: identification of distinct sequences essential for transcription but not replication

The cis-acting genomic RNA requirements for the assembly of vesicular stomatitis virus (VSV) ribonucleocapsids into infectious particles were investigated. Using a biological assay based on particle infectivity, we demonstrated that subgenomic replicons that contained all four possible combinations of the natural genomic termini, the 3' leader (Le) and 5' trailer (Tr) regions, were replication competent; however, a 3' copyback replicon (3'CB), containing the natural 3' terminus but having the 5' Tr replaced by a sequence complementary to the 3' Le for 46 nucleotides, was unable to assemble infectious particles, despite efficient replication. When a copy of Tr was inserted 51 nucleotides from the 5' end of 3'CB, infectious particles were produced. However, analysis of the replication products of these particles showed that the 51 nucleotides which corresponded to the Le complement sequences at the 5' terminus were removed during RNA replication, thus restoring the wild-type 5' Tr to the exact 5' terminus. These data showed that a cis-acting signal was necessary for assembly of VSV RNAs into infectious particles and that this signal was supplied by Tr when located at the 5' end. The regions within Tr required for assembly were analyzed by a series of deletions and exchanges for Le complement sequences, which demonstrated that the 5' terminal 29 nucleotides of Tr allowed assembly of infectious particles but that the 5' terminal 22 nucleotides functioned poorly. Deletions in Tr also altered the balance between negative- and positive-strand genomic RNA and affected levels of replication. RNAs that retained fewer than 45 but at least 22 nucleotides of the 5' terminus could replicate but were impaired in RNA replication, and RNAs that retained only 14 nucleotides of the 5' terminus were severely reduced in ability to replicate. These data define the VSV Tr as a position-dependent, cis-acting element for the assembly of RNAs into infectious particles, and they delineate RNA sequences that are essential for negative-strand RNA synthesis. These observations are consistent with, and offer an explanation for, the absence of 3' copyback defective interfering particles in nature.     

RNA replication for the paramyxovirus simian virus 5 requires an internal repeated (CGNNNN) sequence motif

A functional RNA replication promoter for the paramyxovirus simian virus 5 (SV5) requires two essential and discontinuous elements: 19 bases at the 3' terminus (conserved region I) and an 18-base internal region (conserved region II [CRII]) that is contained within the coding region of the L protein gene. A reverse-genetics system was used to determine the sequence requirements for the internal CRII element to function in RNA replication. A series of copyback defective interfering (DI) RNA analogs were constructed to contain point mutations in the 18 nucleotides composing CRII, and their relative replication levels were analyzed. The results indicated that SV5 DI RNA replication was reduced by substitutions for two CG dinucleotides, which in the nucleocapsid template are in the first two positions of the first two hexamers of CRII nucleotides. Substitutions for other bases within CRII did not reduce RNA synthesis. Thus, two consecutive 5'-CGNNNN-3' hexamers form an important sequence in the SV5 CRII promoter element. The position of the CG dinucleotide within the SV5 leader and antitrailer promoters was highly conserved among other members of the Rubulavirus genus, but this motif differed significantly in both sequence and position from that previously identified for Sendai virus. The possible roles of the CRII internal promoter element in paramyxovirus RNA replication are discussed.     

Effect of ultraviolet irradiation of bacteriophage f1 DNA on its conversion to replicative form by extracts of Escherichia coli

When DNA of phage chiX174 or phage f1 is used as a template after exposure to ultraviolet radiation, the conversion of single-stranded DNA to replicative form by cell-free extracts of Escherichia coli is inhibited. The extend of synthesis is proportional to the distance of a pyrimidine dimer from a specific origin of replication as calculated from the random location of dimers at various UV doses. The results therefore indicate that the initiation of DNA synthesis on these phage DNAs occurs normally at a specific site, and that chain elongation is blocked when replication reaches a photo product in the template. Reinitiation of DNA synthesis distal to the lesion does not occur.     

Structure of the Escherichia coli primase/single-strand DNA-binding protein/phage G4oric complex required for primer RNA synthesis

Escherichia coli primase/SSB/single-stranded phage G4oric is a simple system to study how primase interacts with DNA template to synthesize primer RNA for initiation of DNA replication. By a strategy of deletion analysis and antisense oligonucleotide protection on small single-stranded G4oric fragments, we have identified the DNA sequences required for binding primase and the critical location of single-strand DNA-binding (SSB) protein. Together with the previous data, we have defined the structure of the primase/SSB/G4oric priming complex. Two SSB tetramers bind to the G4oric secondary structure, which dictates the spacing of 3' and 5' bound adjacent SSB tetramers and leaves SSB-free regions on both sides of the stem-loop structure. Two primase molecules then bind separately to specific DNA sequences in the 3' and 5' SSB-free G4oric regions. Binding of the 3' SSB tetramer, upstream of the primer RNA initiation site, is also necessary for priming. The generation of a primase-recognition target by SSB phasing at DNA hairpin structures may be applicable to the binding of initiator proteins in other single-stranded DNA priming systems. Novel techniques used in this study include antisense oligonucleotide protection and RNA synthesis on an SSB-melted, double-stranded DNA template.     

Structural basis for binding of the plasmid ColIb-P9 antisense Inc RNA to its target RNA with the 5'-rUUGGCG-3' motif in the loop sequence

The sequence 5'-rUUGGCG-3' is conserved within the loop regions of antisense RNAs or their targets involved in replication of various prokaryotic plasmids. In IncIalpha plasmid ColIb-P9, the partially base paired 21-nucleotide loop of a stem-loop called structure I within RepZ mRNA contains this hexanucleotide sequence, and comprises the target site for the antisense Inc RNA. In this report, we find that the base pairing interaction at the 5'-rGGC-3' sequence in the hexanucleotide motif is important for interaction between Inc RNA and structure I. In addition, the 21-base loop domain of structure I is folded tighter than predicted, with the hexanucleotide sequence at the top. The second U residue in the sequence is favored for Inc RNA binding in a base-specific manner. On the other hand, the upper domain of the Inc RNA stem-loop is loosely structured, and maintaining the loop sequence single-stranded is important for the intermolecular interaction. Based on these results, we propose that a structural feature in the loop I domain, conferred probably by the conserved 5'-rUUGGCG-3' sequence, favors binding to a complementary, single-stranded RNA. This model also explains how the RepZ mRNA pseudoknot, described in the accompanying paper (Asano, K., and Mizobuchi, K. (1998) J. Biol. Chem. 273, 11815-11825) is formed specifically with structure I. A possible conformation adopted by the 5'-rUUGGCG-3' loop sequence is discussed.     

The enigma of pX: A host-dependent cis-acting element with variable effects on tombusvirus RNA accumulation

Tomato bushy stunt virus (TBSV) is a small isometric virus that contains a single-stranded RNA genome with five major genes. In this study, we have analyzed the importance of an additional small sixth open reading frame (ORF) of 207 nucleotides, designated pX, which resides at the 3' end of the genome. Bioassays showed that deletions or additions of nucleotides at the 5' end of the pX gene that were designed to disrupt the ORF, or site-specific inactivation of its start codon, all gave rise to TBSV mutants which were unable to accumulate to detectable levels in cucumber or Nicotiana benthamiana protoplasts. Although these results suggested a role for the putative pX protein, introduction of a premature stop codon in the pX gene had no strong negative effect. However, a comparable mutation that affected the same nucleotides without changing the predicted amino acid sequence greatly reduced RNA accumulation. Therefore, we hypothesize that cis-acting RNA sequences within the pX gene, rather than the predicted protein influence genome accumulation. The requirement of the cis-acting pX ORF sequences appears to be host-dependent because comparisons revealed that subtle pX gene mutations that prohibited accumulation of TBSV RNA in cucumber or N. benthamiana, failed to interfere substantially with replication in Chenopodium quinoa protoplasts or plants. Irrespective of the host, the cis-acting pX gene sequences were dispensable on replicase-deficient RNAs that require helper TBSV for replication in trans. In addition, the pX gene was not essential for in vitro translation of replicase proteins from genomic RNA. These results suggest that neither translation nor polymerase activity of the replicase proteins require pX gene sequences. However, it is possible that very early in the replication cycle of genomic RNA in vivo, the pX gene cis-acting element is essential for some other unidentified function which involves interaction with one or more host components whose composition varies slightly between different plants.     

Effects of mutations within and adjacent to the terminal repeats of hepatitis B virus pregenomic RNA on viral DNA synthesis

The viral polymerase and several cis-acting sequences are essential for hepadnaviral DNA replication, but additional host factors are likely to be involved in this process. We previously identified two sequences, UBS and DBS (upstream and downstream binding sites), present in multiple copies in and adjacent to the pregenomic RNA (pgRNA) terminal redundancy, that were specifically recognized by a 65-kDa host factor, p65. The possible roles of these two sequences in hepatitis B virus (HBV) replication were investigated in the context of the intact viral genome. UBS is contained within the terminal redundancy of pgRNA, and the 5' copy of this sequence is essential for viral replication. Mutations within the central core of UBS ablate p65 binding and selectively block synthesis of plus-strand DNA, without affecting RNA packaging or minus-strand synthesis. The DBS sequence, which is located downstream of the pgRNA polyadenylation site, overlaps the core (C) protein coding region. All mutations introduced into this site severely affected viral replication. However, these effects were shown to result from dominant negative effects of mutant core polypeptides rather than from cis-acting effects on RNA recognition. Thus, the 5' UBS but not DBS sites play important cis-acting roles in HBV DNA replication; however, the involvement of p65 in these roles remains a matter for investigation.     

High-mobility group 1/2 proteins are essential for initiating rolling-circle-type DNA replication at a parvovirus hairpin origin

Rolling-circle replication is initiated by a replicon-encoded endonuclease which introduces a single-strand nick into specific origin sequences, becoming covalently attached to the 5' end of the DNA at the nick and providing a 3' hydroxyl to prime unidirectional, leading-strand synthesis. Parvoviruses, such as minute virus of mice (MVM), have adapted this mechanism to amplify their linear single-stranded genomes by using hairpin telomeres which sequentially unfold and refold to shuttle the replication fork back and forth along the genome, creating a continuous, multimeric DNA strand. The viral initiator protein, NS1, then excises individual genomes from this continuum by nicking and reinitiating synthesis at specific origins present within the hairpin sequences. Using in vitro assays to study ATP-dependent initiation within the right-hand (5') MVM hairpin, we have characterized a HeLa cell factor which is absolutely required to allow NS1 to nick this origin. Unlike parvovirus initiation factor (PIF), the cellular complex which activates NS1 endonuclease activity at the left-hand (3') viral origin, the host factor which activates the right-hand hairpin elutes from phosphocellulose in high salt, has a molecular mass of around 25 kDa, and appears to bind preferentially to structured DNA, suggesting that it might be a member of the high-mobility group 1/2 (HMG1/2) protein family. This prediction was confirmed by showing that purified calf thymus HMG1 and recombinant human HMG1 or murine HMG2 could each substitute for the HeLa factor, activating the NS1 endonuclease in an origin-specific nicking reaction.