Palindrome regeneration by template strand-switching mechanism at the origin of DNA replication of porcine circovirus via the rolling-circle melting-pot replication model

Palindromic sequences (inverted repeats) flanking the origin of DNA replication with the potential of forming single-stranded stem-loop cruciform structures have been reported to be essential for replication of the circular genomes of many prokaryotic and eukaryotic systems. In this study, mutant genomes of porcine circovirus with deletions in the origin-flanking palindrome and incapable of forming any cruciform structures invariably yielded progeny viruses containing longer and more stable palindromes. These results suggest that origin-flanking palindromes are essential for termination but not for initiation of DNA replication. Detection of template strand switching in the middle of an inverted repeat strand among the progeny viruses demonstrated that both the minus genome and a corresponding palindromic strand served as templates simultaneously during DNA biosynthesis and supports the recently proposed rolling-circle "melting-pot" replication model. The genome configuration presented by this model, a four-stranded tertiary structure, provides insights into the mechanisms of DNA replication, inverted repeat correction (or conversion), and illegitimate recombination of any circular DNA molecule with an origin-flanking palindrome.     

Partial replicas of UV-irradiated bacteriophage T4 genomes and their role in multiplicity reactivation.

A physicochemical study was made of the replication and transmission of UV-irradiated T4 genomes. The data presented in this paper justify the following conclusions. (i) For both low and high multiplicity of infection there was abundant replication from UV-irradiated parental templates. It exceeded by far the efficiency predicted by the hypothesis that a single lethal hit completely prevents replication of the killed phage DNA: i.e., some dead phage particles must replicate parts of thier DNA. (ii) Replication of the UV-irradiated DNA was repetitive as shown by density reversal experiments. (iii) Newly synthesized progeny DNA originating from UV-irradiated templates appeared as significantly shorter segments of the genomes than progeny DNA produced from non-UV-irradiated templates. A good correlation existed between the number of UV hits and the number of random cuts that would be needed to reduce replication fragments to the length observed. (iv) The contribution of UV-irradiated parental DNA among progeny phage in multiplicity reactivation was disposed in shorter subunits than was the DNA from unirradiated parental phage. It is important to emphasize that it was mainly in the form of replicative hybrid. These conclusions appear to justify excluding interparental recombination as a prerequisite for multiplicity reactivation. They lead directly to some form of partial replica hypothesis for multiplicity reactivation.     

An amino-terminal domain of the Sendai virus nucleocapsid protein is required for template function in viral RNA synthesis.

The nucleocapsid protein (NP) of Sendai virus encapsidates the genome RNA, forming a helical nucleocapsid which is the template for RNA synthesis by the viral RNA polymerase. The NP protein is thought to have both structural and functional roles, since it is an essential component of the NP0-P (P, phosphoprotein), NP-NP, nucleocapsid-polymerase, and RNA-NP complexes required during viral RNA replication. To identify domains in the NP protein, mutants were constructed by using clustered charge-to-alanine mutagenesis in a highly charged region from amino acids 107 to 129. Each of the mutants supported RNA encapsidation in vitro. The product nucleocapsids formed with three mutants, NP114, NP121, and NP126, however, did not serve as templates for further amplification in vivo, while NP107, NP108, and NP111 were nearly like wild-type NP in vivo. This template defect in the NP mutants from amino acids 114 to 129 was not due to a lack of NP0-P, NP-NP, or nucleocapsid-polymerase complex formation, since these interactions were normal in these mutants. We propose that amino acids 114 to 129 of the NP protein are required for the nucleocapsid to function as a template in viral genome replication.     

Defective Interference in the Killer System of Saccharomyces cerevisiae

The K₁ killer virus (or plasmid) of Saccharomyces cerevisiae is a noninfectious double-stranded RNA genome found intracellularly packaged in an icosahedral capsid. This genome codes for a protein toxin and for resistance to that toxin. Defective interfering virus mutants are deletion derivatives of the killer virus double-stranded RNA genome; such mutants are called suppressive. Unlike strains carrying the wild-type genome, strains with these deletion derivatives are neither toxin producers nor toxin resistant. If both the suppressive and the wildtype virus are introduced into the same cell, most progeny become toxin-sensitive nonkillers (J. M. Somers, Genetics 74:571-579, 1973). Diploids formed by the mating of a killer with a suppressive strain were grown in liquid culture, and RNA was extracted from samples taken up to 41 generations after the mating. The ratio of killer RNA to suppressive RNA decreased with increasing generations; by 41 generations the killer RNA was barely detectable. The copy numbers of the suppressive genome and its parental killer were virtually the same in isogenic strains, as were the growth rates of diploid strains containing either virus alone. Therefore, suppressiveness, not being due to segregation or overgrowth by faster growing segregants, is likely due to preferential replication or maintenance of the suppressive genome. Three suppressive viruses, all derivatives of the same killer virus (T. K. Sweeney et al., Genetics 84:27-42, 1976), did not coexist stably. The evidence strongly indicates that the largest genome of the three slowly suppressed both of the smaller genomes, showing that larger genomes can suppress smaller ones and that suppression can occur between two suppressives. Of 48 isolates of strains carrying the suppressive viruses, 5 had newly detectable RNA species, all larger than the original suppressive genomes. At least seven genes necessary for maintenance of the wild-type killer virus (MAK genes) were needed by a suppressive mutant. No effect of ski mutations (affecting regulation of killer virus double-stranded RNA replication) on suppressiveness was observed.     

The fate of parental nucleosomes during SV40 DNA replication.

The fate of parental nucleosomes during the replication of chromatin templates was studied using a modification of the cell-free SV40 DNA replication system. Plasmid DNA molecules containing the SV40 origin were assembled into chromatin with purified core histones and fractionated assembly factors derived from HeLa cells. When these templates were replicated in vitro, the resulting progeny retained a nucleosomal organization. To determine whether the nucleosomes associated with the progeny molecules resulted from displacement of parental histones during replication followed by reassembly, the replication reactions were performed in the presence of control templates. It was observed that the progeny genomes resulting from the replication of chromatin templates retained a nucleosomal structure, whereas the progeny of the control DNA molecules were not assembled into chromatin. Additional experiments, involving direct addition of histones to the replication reaction mixtures, confirmed that the control templates were not sequestered in some form which made them unavailable for nucleosome assembly. Thus, our data demonstrate that parental nucleosomes remain associated with the replicating molecules and are transferred to the progeny molecules without displacement into solution. We propose a simple model in which nucleosomes ahead of the fork are transferred intact to the newly synthesized daughter duplexes.     

Molecular genetic and biochemical characterization of the vaccinia virus I3 protein, the replicative single-stranded DNA binding protein

Vaccinia virus, the prototypic poxvirus, efficiently and faithfully replicates its ～200-kb DNA genome within the cytoplasm of infected cells. This intracellular localization dictates that vaccinia virus encodes most, if not all, of its own DNA replication machinery. Included in the repertoire of viral replication proteins is the I3 protein, which binds to single-stranded DNA (ssDNA) with great specificity and stability and has been presumed to be the replicative ssDNA binding protein (SSB). We substantiate here that I3 colocalizes with bromodeoxyuridine (BrdU)-labeled nascent viral genomes and that these genomes accumulate in cytoplasmic factories that are delimited by membranes derived from the endoplasmic reticulum. Moreover, we report on a structure/function analysis of I3 involving the isolation and characterization of 10 clustered charge-to-alanine mutants. These mutants were analyzed for their biochemical properties (self-interaction and DNA binding) and biological competence. Three of the mutant proteins, encoded by the I3 alleles I3-4, -5, and -7, were deficient in self-interaction and unable to support virus viability, strongly suggesting that the multimerization of I3 is biologically significant. Mutant I3-5 was also deficient in DNA binding. Additionally, we demonstrate that small interfering RNA (siRNA)-mediated depletion of I3 causes a significant decrease in the accumulation of progeny genomes and that this reduction diminishes the yield of infectious virus.     

Deletion mapping of Sindbis virus DI RNAs derived from cDNAs defines the sequences essential for replication and packaging

Defective-interfering (DI) genomes of a virus contain sequence information essential for their replication and packaging. They need not contain any coding information and therefore are a valuable tool for identifying cis-acting, regulatory sequences in a viral genome. To identify these sequences in a DI genome of Sindbis virus, we cloned a cDNA copy of a complete DI genome directly downstream of the promoter for the SP6 bacteriophage DNA dependent RNA polymerase. The cDNA was transcribed into RNA, which was transfected into chicken embryo fibroblasts in the presence of helper Sindbis virus. After one to two passages the DI RNA became the major viral RNA species in infected cells. Data from a series of deletions covering the entire DI genome show that only sequences in the 162 nucleotide region at the 5' terminus and in the 19 nucleotide region at the 3' terminus are specifically required for replication and packaging of these genomes.     

Arterivirus Nsp1 Modulates the Accumulation of Minus-Strand Templates to Control the Relative Abundance of Viral mRNAs

The gene expression of plus-strand RNA viruses with a polycistronic genome depends on translation and replication of the genomic mRNA, as well as synthesis of subgenomic (sg) mRNAs. Arteriviruses and coronaviruses, distantly related members of the nidovirus order, employ a unique mechanism of discontinuous minus-strand RNA synthesis to generate subgenome-length templates for the synthesis of a nested set of sg mRNAs. Non-structural protein 1 (nsp1) of the arterivirus equine arteritis virus (EAV), a multifunctional regulator of viral RNA synthesis and virion biogenesis, was previously implicated in controlling the balance between genome replication and sg mRNA synthesis. Here, we employed reverse and forward genetics to gain insight into the multiple regulatory roles of nsp1. Our analysis revealed that the relative abundance of viral mRNAs is tightly controlled by an intricate network of interactions involving all nsp1 subdomains. Distinct nsp1 mutations affected the quantitative balance among viral mRNA species, and our data implicate nsp1 in controlling the accumulation of full-length and subgenome-length minus-strand templates for viral mRNA synthesis. The moderate differential changes in viral mRNA abundance of nsp1 mutants resulted in similarly altered viral protein levels, but progeny virus yields were greatly reduced. Pseudorevertant analysis provided compelling genetic evidence that balanced EAV mRNA accumulation is critical for efficient virus production. This first report on protein-mediated, mRNA-specific control of nidovirus RNA synthesis reveals the existence of an integral control mechanism to fine-tune replication, sg mRNA synthesis, and virus production, and establishes a major role for nsp1 in coordinating the arterivirus replicative cycle.     

Replication of tobacco mosaic virus RNA

The replication of tobacco mosaic virus (TMV) RNA involves synthesis of a negative-strand RNA using the genomic positive-strand RNA as a template, followed by the synthesis of positive-strand RNA on the negative-strand RNA templates. Intermediates of replication isolated from infected cells include completely double-stranded RNA (replicative form) and partly double-stranded and partly single-stranded RNA (replicative intermediate), but it is not known whether these structures are double-stranded or largely single-stranded in vivo. The synthesis of negative strands ceases before that of positive strands, and positive and negative strands may be synthesized by two different polymerases. The genomic-length negative strand also serves as a template for the synthesis of subgenomic mRNAs for the virus movement and coat proteins. Both the virus-encoded 126-kDa protein, which has amino-acid sequence motifs typical of methyltransferases and helicases, and the 183-kDa protein, which has additional motifs characteristic of RNA-dependent RNA polymerases, are required for efficient TMV RNA replication. Purified TMV RNA polymerase also contains a host protein serologically related to the RNA-binding subunit of the yeast translational initiation factor, eIF3. Study of Arabidopsis mutants defective in RNA replication indicates that at least two host proteins are needed for TMV RNA replication. The tomato resistance gene Tm-1 may also encode a mutant form of a host protein component of the TMV replicase. TMV replicase complexes are located on the endoplasmic reticulum in close association with the cytoskeleton in cytoplasmic bodies called viroplasms, which mature to produce 'X bodies'. Viroplasms are sites of both RNA replication and protein synthesis, and may provide compartments in which the various stages of the virus mutiplication cycle (protein synthesis, RNA replication, virus movement, encapsidation) are localized and coordinated. Membranes may also be important for the configuration of the replicase with respect to initiation of RNA synthesis, and synthesis and release of progeny single-stranded RNA.     

Emergence of distinct brome mosaic virus recombinants is determined by the polarity of the inoculum RNA

Despite overwhelming interest in the impact exerted by recombination during evolution of RNA viruses, the relative contribution of the polarity of inoculum templates remains poorly understood. Here, by agroinfiltrating Nicotiana benthamiana leaves, we show that brome mosaic virus (BMV) replicase is competent to initiate positive-strand [(+)-strand] synthesis on an ectopically expressed RNA3 negative strand [(-) strand] and faithfully complete the replication cycle. Consequently, we sought to examine the role of RNA polarity in BMV recombination by expressing a series of replication-defective mutants of BMV RNA3 in (+) or (-) polarity. Temporal analysis of progeny sequences revealed that the genetic makeup of the primary recombinant pool is determined by the polarity of the inoculum template. When the polarity of the inoculum template was (+), the recombinant pool that accumulated during early phases of replication was a mixture of nonhomologous recombinants. These are longer than the inoculum template length, and a nascent 3' untranslated region (UTR) of wild-type (WT) RNA1 or RNA2 was added to the input mutant RNA3 3' UTR due to end-to-end template switching by BMV replicase during (-)-strand synthesis. In contrast, when the polarity of the inoculum was (-), the progeny contained a pool of native-length homologous recombinants generated by template switching of BMV replicase with a nascent UTR from WT RNA1 or RNA2 during (+)-strand synthesis. Repair of a point mutation caused by polymerase error occurred only when the polarity of the inoculum template was (+). These results contribute to the explanation of the functional role of RNA polarity in recombination mediated by copy choice mechanisms.     

Mutations that decrease DNA binding of the processivity factor of the herpes simplex virus DNA polymerase reduce viral yield, alter the kinetics of viral DNA replication, and decrease the fidelity of DNA replication

The processivity subunit of the herpes simplex virus DNA polymerase, UL42, is essential for viral replication and possesses both Pol- and DNA-binding activities. Previous studies demonstrated that the substitution of alanine for each of four arginine residues, which reside on the positively charged surface of UL42, resulted in decreased DNA binding affinity and a decreased ability to synthesize long-chain DNA by the polymerase. In this study, the effects of each substitution on the production of viral progeny, viral DNA replication, and DNA replication fidelity were examined. Each substitution mutant was able to complement the replication of a UL42 null mutant in transient complementation assays and to support the replication of plasmid DNA containing herpes simplex virus type 1 (HSV-1) origin sequences in transient DNA replication assays. Mutant viruses containing each substitution and a lacZ insertion in a nonessential region of the genome were constructed and characterized. In single-cycle growth assays, the mutants produced significantly less progeny virus than the control virus containing wild-type UL42. Real-time PCR assays revealed that these UL42 mutants synthesized less viral DNA during the early phase of infection. Interestingly, during the late phase of infection, the mutant viruses synthesized larger amounts of viral DNA than the control virus. The frequencies of mutations of the virus-borne lacZ gene increased significantly in the substitution mutants compared to those observed for the control virus. These results demonstrate that the reduced DNA binding of UL42 is associated with significant effects on virus yields, viral DNA replication, and replication fidelity. Thus, a processivity factor can influence replication fidelity in mammalian cells.