ATPase switches controlling DNA replication initiation

Proteins that bind and hydrolyze ATP are frequently involved in the early steps of DNA replication. Recent studies of Saccharomyces cerevisiae suggest that two members of the AAA+ ATPase family--the origin recognition complex and Cdc6p--have separable roles for ATP binding and ATP hydrolysis during eukaryotic DNA replication. Intriguingly, the proposed regulation of these eukaryotic replication proteins by ATP has functional similarities to the ATP-dependent control of the DnaA and DnaC initiation factors from Escherichia coli. Comparison of the ATP regulation of these factors suggests that ATP binding and hydrolysis acts as a molecular switch that couples key events during initiation of replication. This switch results in a significant change in protein function.     

Mechanism of the E. coli tau processivity switch during lagging-strand synthesis

The E. coli replication machinery employs a beta clamp that tethers the polymerase to DNA, thus ensuring high processivity. The replicase also contains a processivity switch that dissociates the polymerase from its beta clamp. The switch requires the tau subunit of the clamp loader and is regulated by different DNA structures. At a primed site, the switch is "off." When the replicase reaches the downstream primer to form a nick, the switch is flipped, and tau ejects the polymerase from beta. This switch has high fidelity for completed synthesis, remaining "off" until just prior to incorporation of the last nucleotide and turning "on" only after addition of the last dNTP. These actions of tau are confined to its C-terminal region, which is located outside the clamp loading apparatus. Thus, this highly processive replication machine has evolved a mechanism to specifically counteract processivity at a defined time in the lagging-strand cycle.     

Physical mapping of an origin of bidirectional replication at the centre of the Borrelia burgdorferi linear chromosome

The Borrelia burgdorferi chromosome is linear, with telomeres characterized by terminal inverted repeats and covalently closed single-stranded hairpin loops. The replication mechanism of these unusual molecules is unknown. Previous analyses of bacterial chromosomes for which the complete sequence has been determined, including that of B. burgdorferi, revealed an abrupt switch in polarity of CG skew at known or putative origins of replication. We used nascent DNA strand analysis to physically map the B. burgdorferi origin to within a 2 kb region at the centre of the linear chromosome, and to show that replication proceeds bidirectionally from this origin. The results are consistent with replication models in which termination occurs at the telomeres after bidirectional, symmetrical elongation from the central origin. Sequences typical of origins of other bacterial chromosomes were not found at the origin of this spirochete. The most likely location of the replication origin of the linear chromosome is the 240 bp sequence between dnaA and dnaN where the switch in CG skew occurs.     

Regional and temporal changes in the pattern of X-chromosome replication during the early post-implantation development of the female mouse

We have made a detailed study of the X-chromosome replication pattern during the period when X-inactivation is occurring in the mouse embryo. Our observations show unequivocal regionalization of the embryo with respect to the temporal appearance, parental origin and DNA replication pattern of the allocyclic X-chromosome. The switch from isocyclic to allocyclic replication occurs in the embryonic ectoderm at approximately 6 days of development and is random with respect to parental origin of the X-chromosome. In the extra-embryonic tissues, however, the switch to allocyclic replication has apparently occurred prior to 5.3 days of development and almost exclusively involves the paternally-derived X-chromosome. Since these findings are consistent with results obtained in biochemical studies of X-chromosome activity in female embryos, we conclude that there is a close temporal relationship between the cytogenetic and biochemical manifestations of the X-inactivation process. In addition, we have observed a pattern of early paternal X-chromosome replication, transitory in some cases, that is unique to extra-embryonic tissues. These results suggest that there may be some differences in the mechanism by which X-inactivation occurs in the extra-embryonic tissues as compared with the embryonic ectoderm.     

DNA repeat rearrangements mediated by DnaK-dependent replication fork repair

We propose that rearrangements between short tandem repeated sequences occur by errors made during a replication fork repair pathway involving a replication template switch. We provide evidence here that the DnaK chaperone of E. coli controls this template switch repair process. Mutants in dnaK are sensitive to replication fork damage and exhibit high expression of the SOS response, indicative of repair deficiency. Deletion and expansion of tandem repeats that occur by replication misalignment ("slippage") are also DnaK dependent. Because mutations in dnaX encoding the gamma and tau subunits of DNA polymerase III mimic dnaK phenotypes and are genetically epistatic, we propose that the DnaKJ chaperone remodels the replisome to facilitate repair. The fork remains largely intact because PriA or PriC restart proteins are not required. We also suggest that the poorly defined RAD6-RAD18-RAD5 mechanism of postreplication repair in eukaryotes occurs by an analogous mechanism to the DnaK template-switch pathway in prokaryotes.     

Herpesvirus saimiri open reading frame 50 (Rta) protein reactivates the lytic replication cycle in a persistently infected A549 cell line

Herpesviruses occur in two distinct forms of infection, lytic replication and latent persistence. In this study, we investigated the molecular mechanisms that govern the latent-lytic switch in the prototype gamma-2 herpesvirus, herpesvirus saimiri (HVS). We utilized a persistently HVS-infected A549 cell line, in which HVS DNA is stably maintained as nonintegrated circular episomes, to assess the role of the open reading frame 50 (ORF 50) (Rta) proteins in the latent-lytic switch. Northern blot analysis and virus recovery assays determined that the ORF 50a gene product, when expressed under the control of a constitutively active promoter, was sufficient to reactivate the entire lytic replication cycle, producing infectious virus particles. Furthermore, although the ORF 50 proteins of HVS strains A11 and C488 are structurally divergent, they were both capable of inducing the lytic replication cycle in this model of HVS latency.     

Cellular protein modification by poliovirus: the two faces of poly(rC)-binding protein

During picornavirus infection, several cellular proteins are cleaved by virus-encoded proteinases. Such cleavage events are likely to be involved in the changing dynamics during the intracellular viral life cycle, from viral translation to host shutoff to RNA replication to virion assembly. For example, it has been proposed that there is an active switch from poliovirus translation to RNA replication mediated by changes in RNA-binding protein affinities. This switch could be a mechanism for controlling template selection for translation and negative-strand viral RNA synthesis, two processes that use the same positive-strand RNA as a template but proceed in opposing directions. The cellular protein poly(rC)-binding protein (PCBP) was identified as a primary candidate for regulating such a mechanism. Among the four different isoforms of PCBP in mammalian cells, PCBP2 is required for translation initiation on picornavirus genomes with type I internal ribosome entry site elements and also for RNA replication. Through its three K-homologous (KH) domains, PCPB2 forms functional protein-protein and RNA-protein complexes with components of the viral translation and replication machinery. We have found that the isoforms PCBP1 and -2 are cleaved during the mid-to-late phase of poliovirus infection. On the basis of in vitro cleavage assays, we determined that this cleavage event was mediated by the viral proteinases 3C/3CD. The primary cleavage occurs in the linker between the KH2 and KH3 domains, resulting in truncated PCBP2 lacking the KH3 domain. This cleaved protein, termed PCBP2-DeltaKH3, is unable to function in translation but maintains its activity in viral RNA replication. We propose that through the loss of the KH3 domain, and therefore loss of its ability to function in translation, PCBP2 can mediate the switch from viral translation to RNA replication.     

Intrinsic obstacles to human immunodeficiency virus type 1 coreceptor switching

The natural evolution of human immunodeficiency virus type 1 infection often includes a switch in coreceptor preference late in infection from CCR5 to CXCR4, a change associated with expanded target cell range and worsened clinical prognosis. Why coreceptor switching takes so long is puzzling, since it requires as few as one to two mutations. Here we report three obstacles that impede the CCR5-to-CXCR4 switch. Coreceptor switch variants were selected by target cell replacement in vitro. Most switch variants showed diminished replication compared to their parental R5 isolate. Transitional intermediates were more sensitive to both CCR5 and CXCR4 inhibitors than either the parental R5 virus or the final R5X4 (or rare X4) variant. The small number of mutations in viruses selected for CXCR4 use were distinctly nonrandom, with a dominance of charged amino acid substitutions encoded by G-to-A transitions, changes in N-linked glycosylation sites, and isolate-specific mutation patterns. Diminished replication fitness, less-efficient coreceptor use, and unique mutational pathways may explain the long delay from primary infection until the emergence of CXCR4-using viruses.     

Role of the NS gene in regulating the synthesis of RNA-segments of the influenza A virus

To find the role of any influenza virus gene in regulation of the RNA-segments replication the transfer of ts-mutants to nonpermissive temperature on the late step of infection has been used (shift-up). The mutants having impaired the NS or NP-genes have been obtained and studied. The transfer of mutants to partially nonpermissive conditions (when the amount of replication is decreased, but it still continues) results in the distinct return to the early mode of replication in ts-mutant with the mutation in NS-gene. This suggests the NS-gene role in replication of viral RNA-segments, in particular, in the switch from the "early" stage of replication to the "late" one. In NP-gene mutant only the decrease in general replication takes place without the shift to "early" replication mode.     

From gene to chromosome: organization levels defined by the interplay of transcription and replication in vertebrates

In higher eukaryotes, gene activation is accompanied by an increased sensitivity to DNaseI over a domain that extends beyond the limits of the gene itself, or of the gene cluster to which it belongs. This increased sensitivity probably reflects both the partial decondensation of chromatin and an increased communication with the outside of the nucleus. In addition, gene activation usually causes a coreplication domain that extends much beyond the decondensation domain to switch to an early replication time in S phase. This switch is produced, at least in some cases, by an early firing of origins of replication situated in flanking condensed chromatin. Some of the recently identified DNA domains that tether chromosomal loops to the nuclear matrix do represent the borders of decondensation domains. They may also constitute pausing sites for replication forks. The different replication times of successive 200- to 400-kb regions along the genome may have been the basis for the observed long-term differentiation of very large genomes in domains of different overall sequence composition (G:C content and distribution of short repeated motifs). Chromosomal bands represent a low resolution picture of this pattern. Just like gene methylation, differential replication timing and the consequent compositional differentiation of the genome have probably contributed to making the management of very large genomes workable.     

Evidence for a switch in the mode of human papillomavirus type 16 DNA replication during the viral life cycle.

The study of human papillomavirus type 16 (HPV-16) replication has been impaired because of the lack of a cell culture system that stably maintains viral replication. Recently, cervical epithelial cell populations that stably maintain HPV-16 replicons at a copy number of approximately 1,000 per cell were derived from an HPV-16-infected patient (W12 cell clone 20863 [W12-E cells]). We used neutral/neutral and neutral/alkaline two-dimensional gel electrophoretic techniques to characterize HPV-16 DNA replication in these cells. When W12-E cells were maintained in an undifferentiated state mimicking the nonproductive stage of the life cycle, HPV-16 DNA was found to replicate primarily by theta structures in a bidirectional manner. The initiation site of HPV-16 DNA replication was mapped to approximately nucleotide 100, and the termination site was mapped to between nucleotides 3398 and 5990. To study the productive stage of HPV-16 DNA replication, W12-E cells were grown under culture conditions that promote differentiation of epithelial cell types. Under these conditions, where virus-like particles were detected, the mode of viral DNA replication changed from theta structure to what is apparently a rolling circle mode. Additionally, CIN 612-9E cells, which were derived from an HPV-31-infected patient and harbor HPV-31 extrachromosomally, exhibited the same switch in the mode of DNA replication upon induction of differentiation. These data argue that a fundamental switch in the mechanism of viral DNA replication occurs during the life cycle of the papillomavirus.     

STT3B-dependent posttranslational N-glycosylation as a surveillance system for secretory protein

The chemical identity and integrity of the genome is challenged by the incorporation of ribonucleoside triphosphates (rNTPs) in place of deoxyribonucleoside triphosphates (dNTPs) during replication. Misincorporation is limited by the selectivity of DNA replicases. We show that accumulation of ribonucleoside monophosphates (rNMPs) in the genome causes replication stress and has toxic consequences, particularly in the absence of RNase H1 and RNase H2, which remove rNMPs. We demonstrate that postreplication repair (PRR) pathways-MMS2-dependent template switch and Pol ζ-dependent bypass-are crucial for tolerating the presence of rNMPs in the chromosomes; indeed, we show that Pol ζ efficiently replicates over 1-4 rNMPs. Moreover, cells lacking RNase H accumulate mono- and polyubiquitylated PCNA and have a constitutively activated PRR. Our findings describe a crucial function for RNase H1, RNase H2, template switch, and translesion DNA synthesis in overcoming rNTPs misincorporated during DNA replication, and may be relevant for the pathogenesis of Aicardi-Goutières syndrome.