Effects of reovirus infection on the spatial and temporal organization of DNA replication in L cells

DNA fiber autoradiography was used to analyze the spatial and temporal organization of activated initiation sites for DNA replication in mouse L929 cells infected with reovirus type 3 (Dearing strain) and in uninfected control cells. Cells were labeled for 10 min with³H-thymidine at high specific activity followed by 3 h of low specific activity labeling. Reovirus infection causes no change in the rate of replication fork progression, but increases both the mean distance between activated initiation sites by 30% and the nonrandomness in the spatial distribution of the sites along the DNA fibers. Significant synchronization of initiation in adjacent activated sites was detected on DNA fibers from uninfected cells and from reovirusinfected cells. The mean relative initiation time for pairs of initiation events which had occurred prior to high specific activity labeling did not differ significantly between the infected and uninfected cells. The data are consistent with the interpretation that reovirus infection shuts off initiation sites in a coordinated fashion, possibly by preventing activation of entire clusters of potential initiation sites.     

Temporal organization of replication in DNA fibers of mammalian cells

The extent of coordinate control over the multiple initiation events in DNA replication has been investigated in three mammalian cell lines by DNA fiber autoradiography. Quantitative estimates have been obtained of the degree of synchrony among initiations occurring on stretches of DNA. Synchrony decreases markedly with increasing distance between initiation sites in MDBK (bovine) and L929 (mouse) cells, but only slightly in muntjac cells. Possible control mechanisms for the initiation process are discussed.     

Replication initiation in mammalian cells: changing preferences

Accurate duplication of genetic material is central to cell proliferation. In eukaryotes, S phase is tightly controlled during development. For example, initiation events occur at random sites in early embryos but later appear restricted to preferred DNA regions. Epigenetic changes depending on chromatin organization and/or availability of specific factors likely control origin choice. By using the dynamic molecular combing technology, coupled with specific labeling of neo-synthesized DNA and FISH, we recently demonstrated that the efficiency and spacing of initiation sites are still flexible in mammalian somatic cells, and strongly rely on nucleotide availability. In all conditions, initiation events appear confined to short AT-rich sequences previously identified as matrix attachment regions, which suggests a direct involvement of these features in origin specification. Functional relationships between matrix anchorage and origin selection are discussed.     

DNA replication origin interference increases the spacing between initiation events in human cells

Mammalian DNA replication origins localize to sites that range from base pairs to tens of kilobases. A regular distribution of initiations in individual cell cycles suggests that only a limited number of these numerous potential start sites are converted into activated origins. Origin interference can silence redundant origins; however, it is currently unknown whether interference participates in spacing functional human initiation events. By using a novel hybridization strategy, genomic Morse code, on single combed DNA molecules from primary keratinocytes, we report the initiation sites present on 1.5 Mb of human chromosome 14q11.2. We confirm that initiation zones are widespread in human cells, map to intergenic regions, and contain sequence motifs found at other mammalian initiation zones. Origins used per cell cycle are less abundant than the potential sites of initiation, and their limited use increases the spacing between initiation events. Between-zone interference decreases in proportion to the distance from the active origin, whereas within-zone interference is 100% efficient. These results identify a hierarchical organization of origin activity in human cells. Functional origins govern the probability that nearby origins will fire in the context of multiple potential start sites of DNA replication, and this is mediated by origin interference.     

Plasticity of DNA replication initiation in Epstein-Barr virus episomes

In mammalian cells, the activity of the sites of initiation of DNA replication appears to be influenced epigenetically, but this regulation is not fully understood. Most studies of DNA replication have focused on the activity of individual initiation sites, making it difficult to evaluate the impact of changes in initiation activity on the replication of entire genomic loci. Here, we used single molecule analysis of replicated DNA (SMARD) to study the latent duplication of Epstein-Barr virus (EBV) episomes in human cell lines. We found that initiation sites are present throughout the EBV genome and that their utilization is not conserved in different EBV strains. In addition, SMARD shows that modifications in the utilization of multiple initiation sites occur across large genomic regions (tens of kilobases in size). These observations indicate that individual initiation sites play a limited role in determining the replication dynamics of the EBV genome. Long-range mechanisms and the genomic context appear to play much more important roles, affecting the frequency of utilization and the order of activation of multiple initiation sites. Finally, these results confirm that initiation sites are extremely redundant elements of the EBV genome. We propose that these conclusions also apply to mammalian chromosomes.     

High‐resolution analysis of DNA synthesis start sites and nucleosome architecture at efficient mammalian replication origins

DNA replication origins are poorly characterized genomic regions that are essential to recruit and position the initiation complex to start DNA synthesis. Despite the lack of specific replicator sequences, initiation of replication does not occur at random sites in the mammalian genome. This has lead to the view that DNA accessibility could be a major determinant of mammalian origins. Here, we performed a high‐resolution analysis of nucleosome architecture and initiation sites along several origins of different genomic location and firing efficiencies. We found that mammalian origins are highly variable in nucleosome conformation and initiation patterns. Strikingly, initiation sites at efficient CpG island‐associated origins always occur at positions of high‐nucleosome occupancy. Origin recognition complex (ORC) binding sites, however, occur at adjacent but distinct positions marked by labile nucleosomes. We also found that initiation profiles mirror nucleosome architecture, both at endogenous origins and at a transgene in a heterologous system. Our studies provide a unique insight into the relationship between chromatin structure and initiation sites in the mammalian genome that has direct implications for how the replication programme can be accommodated to diverse epigenetic scenarios.     

DNA synthesis in polyoma virus infection. II. Relationship between viral DNA replication and initiation of cellular DNA replicons

The rate of synthesis of cellular DNA is stimulated in stationary phase mouse embryo cells infected with polyoma virus. Nascent cellular DNA strands pulselabeled with [³H]thymidine in the presence of replicating viral DNA are smaller, by an average of 2·1 × 10⁷ daltons, than DNA made under similar conditions in uninfected cells. Previous work (Cheevers et al., 1972) has indicated that this observation is the consequence of activation in infected cells of cellular DNA initiation sites not in operation during a similar pulse-labeling interval in uninfected cells. Similar results were obtained using cells infected with the temperature-sensitive Ts-a mutant of polyoma at 32 °C, which permits both the induction of cellular DNA synthesis and replication of viral DNA. However, at a temperature of 39 °C, which permits only the induction of cellular DNA replication in Ts-a-infected cells, the size of newly synthesized DNA is not different from that of uninfected cells. Similarly, in rat embryo cells abortively infected with polyoma (wild-type), stimulation of cellular DNA synthesis occurs but viral DNA replication is restricted, and no difference is apparent in the size of newly formed DNA as compared to uninfected cells. These results are interpreted to mean that in productively infected cells, polyoma DNA and some regions of the host genome may be co-ordinately replicated.     

Role of the host cell in persistent viral infection: Coevolution of L cells and reovirus during persistent infection

Mutant L cells, designated LR cells, were isolated after “curing” a persistently infected cell line (L/C) with antireovirus serum. The LR cells were shown to be virus-free; no reovirus was detectable by infectious center assays, plaque assays, presence of viral proteins, presence of viral dsRNA and immunofluorescence studies. Persistent infections were readily established in LR cells following infection with either cloned, low passage wild-type reovirus or cloned, low passage reovirus isolated from carrier cultures. Reovirus isolated from carrier cultures, however, grew much better than wild-type reovirus in LR cells and showed complete dominance over wild-type reovirus in coinfection experiments. Infection of LR cells with wild-type reovirus resulted in a low-level persistent infection with inefficient viral replication; these mutant L cells were partially resistant to infection with wild-type reovirus. In contrast, infection of the mutant L cells with virus isolated from the persistently infected cells resulted in a persistent infection accompanied with efficient viral replication. Infection of the original L cells with either wild-type reovirus or reovirus isolated from the persistently infected cells resulted in a lytic infection with no surviving cells. Thus the host cell plays a crucial role in the maintenance of persistent reovirus infection. Our results show that there is a coevolution of both mutant L cells and mutant reovirus during persistent infection.     

Initiation of latent DNA replication in the Epstein-Barr virus genome can occur at sites other than the genetically defined origin.

Our laboratory has previously shown that replication of a small plasmid, p174, containing the genetically defined Epstein-Barr virus (EBV) latent origin of replication, oriP, initiates within oriP at or near a dyad symmetry (DS) element and terminates specifically at a family of repeated sequences (FR), also located within oriP. We describe here an analysis of the replication of intact approximately 170-kb EBV genomes in four latently infected cell lines that uses two-dimensional gel replicon mapping. Initiation was detected at oriP in all EBV genomes examined; however, some replication forks appear to originate from alternative initiation sites. In addition, pausing of replication forks was observed at the two clusters of EBV nuclear antigen 1 binding sites within oriP and at or near two highly expressed viral genes 0.5 to 1 kb upstream of oriP, the EBV-encoded RNA (EBER) genes. In the Raji EBV genome, the relative abundance of these stalled forks and the direction in which they are stalled indicate that most replication forks originate upstream of oriP. We thus searched for additional initiation sites in the Raji EBV and found that the majority of initiation events were distributed over a broad region to the left of oriP. This delocalized pattern of initiation resembles initiation of replication in several well-characterized mammalian chromosomal loci and is the first described for any viral genome. EBV thus provides a unique model system with which to investigate factors influencing the selection of replication initiation and termination sites in mammalian cells.     

Regulation of DNA replication on subchromosomal units of mammalian cells

The regulation of DNA replication at a subchromosomal level in mammalian cells has been investigated. DNA fiber autoradiographs were prepared from mouse L-929 cells pulse labeled with (3H)thymidine. Initiation events and subsequent chain growth occurring over short stretches (up to three replication units in length) of chromosomal DNA were analyzed. The results show that adjacent units usually initiate replication synchronously and that this synchrony is related to the proximity of initiation sites. In addition, adjacent units are of similar size and the rates of replication fork progression within units and on adjacent units are similar. The rate of fork progression increases with increasing replication unit size. Finally, no evidence for fixed termination sites for the units has been found. These observations suggest that despite large variations in size of replication units, timing of initiation events, and rates of fork progression found in chromosomal DNA as a whole, these processes are closely regulated within subchromosomal clusters of active replication units.     

Dynamics of DNA replication in mammalian somatic cells: nucleotide pool modulates origin choice and interorigin spacing

Selection of active origins and regulation of interorigin spacing are poorly understood in mammalian cells. Using tricolor analysis of combed DNA molecules, we studied an amplified locus containing the known origin, oriGNAI3. We visualized replication firing events at this and other discrete regions and established a strict correlation between AT richness and initiation sites. We found that oriGNAI3 is the prominent origin of the domain, the firing of which correlates with silencing of neighboring sites and establishes large interorigin distances. We demonstrate that cells reversibly respond to a reduction in nucleotide availability by slowing the rate of replication fork progression; in addition, the efficiency of initiation at oriGNAI3 is lowered while other normally dormant origins in the region are activated, which results in an overall increase in the density of initiation events. Thus, nucleotide pools are involved in the specification of active origins, which in turn defines their density along chromosomes.     

Cellular integrity is required for inhibition of initiation of cellular DNA synthesis by reovirus type 3.

Synchronized HeLa cells, primed for entry into the synthesis phase by amethopterin, were prevented from initiating DNA synthesis 9 h after infection with reovirus type 3. However, nuclei isolated from synchronized cells infected with reovirus for 9 or 16 h demonstrated a restored ability to synthesize DNA. The addition of enucleated cytoplasmic extracts from infected or uninfected cells did not affect this restored capacity for synthesis. The addition of ribonucleotide triphosphates to nuclei isolated from infected cells stimulated additional DNA synthesis, suggesting that these nuclei were competent to initiate new rounds of DNA replication. Permeabilization of infected cells did not restore the ability of these cells to synthesize DNA. Nucleoids isolated from intact or permeabilized cells, infected for 9 or 16 h displayed an increased rate of sedimentation when compared with nucleoids isolated from uninfected cells. Nucleoids isolated from the nuclei of infected cells demonstrated a rate of sedimentation similar to that of nucleoids isolated from the nuclei of uninfected cells. The inhibition of initiation of cellular DNA synthesis by reovirus type 3 appears not to have been due to a permanent alteration of the replication complex, but this inhibition could be reversed by the removal of that complex from factors unique to the structural or metabolic integrity of the infected cell.     

JAM-A-independent, antibody-mediated uptake of reovirus into cells leads to apoptosis

Apoptosis plays a major role in the cytopathic effect induced by reovirus following infection of cultured cells and newborn mice. Strain-specific differences in the capacity of reovirus to induce apoptosis segregate with the S1 and M2 gene segments, which encode attachment protein σ1 and membrane penetration protein μ1, respectively. Virus strains that bind to both junctional adhesion molecule-A (JAM-A) and sialic acid are the most potent inducers of apoptosis. In addition to receptor binding, events in reovirus replication that occur during or after viral disassembly but prior to initiation of viral RNA synthesis also are required for reovirus-induced apoptosis. To determine whether reovirus infection initiated in the absence of JAM-A and sialic acid results in apoptosis, Chinese hamster ovary (CHO) cells engineered to express Fc receptors were infected with reovirus using antibodies directed against viral outer-capsid proteins. Fc-mediated infection of CHO cells induced apoptosis in a σ1-independent manner. Apoptosis following this uptake mechanism requires acid-dependent proteolytic disassembly, since treatment of cells with the weak base ammonium chloride diminished the apoptotic response. Analysis of T1L × T3D reassortant viruses revealed that the μ1-encoding M2 gene segment is the only viral determinant of the apoptosis-inducing capacity of reovirus when infection is initiated via Fc receptors. Additionally, a temperature-sensitive, membrane penetration-defective M2 mutant, tsA279.64, is an inefficient inducer of apoptosis. These data suggest that signaling pathways activated by binding of σ1 to JAM-A and sialic acid are dispensable for reovirus-mediated apoptosis and that the μ1 protein plays an essential role in stimulating proapoptotic signaling.