Replication of the simian virus 40 chromosome with purified proteins

Direct single-molecule observations of DNA unwinding by SV40 large tumor antigen under a negative DNA supercoil state

Superhelices, which are induced by the twisting and coiling of double-helical DNA in chromosomes, are thought to affect transcription, replication, and other DNA metabolic processes. In this study, we report the effects of negative supercoiling on the unwinding activity of simian virus 40 large tumor antigen (SV40 TAg) at a single-molecular level. The supercoiling density of linear DNA templates was controlled using magnetic tweezers and monitored using a fluorescent microscope in a flow cell. SV40 TAg-mediated DNA unwinding under relaxed and negative supercoil states was analyzed by the direct observation of both single- and double-stranded regions of single DNA molecules. Increased negative superhelicity stimulated SV40 TAg-mediated DNA unwinding more strongly than a relaxed state; furthermore, negative superhelicity was associated with an increased probability of SV40 TAg-mediated DNA unwinding. These results suggest that negative superhelicity helps to regulate the initiation of DNA replication.

Baculoviruses and nucleosome management

Negatively-supercoiled-ds DNA molecules, including the genomes of baculoviruses, spontaneously wrap around cores of histones to form nucleosomes when present within eukaryotic nuclei. Hence, nucleosome management should be essential for baculovirus genome replication and temporal regulation of transcription, but this has not been documented. Nucleosome mobilization is the dominion of ATP-dependent chromatin-remodeling complexes. SWI/SNF and INO80, two of the best-studied complexes, as well as chromatin modifier TIP60, all contain actin as a subunit. Retrospective analysis of results of AcMNPV time course experiments wherein actin polymerization was blocked by cytochalasin D drug treatment implicate actin-containing chromatin modifying complexes in decatenating baculovirus genomes, shutting down host transcription, and regulating late and very late phases of viral transcription. Moreover, virus-mediated nuclear localization of actin early during infection may contribute to nucleosome management.

Molecular traffic jams on DNA

All aspects of DNA metabolism-including transcription, replication, and repair-involve motor enzymes that move along genomic DNA. These processes must all take place on chromosomes that are occupied by a large number of other proteins. However, very little is known regarding how nucleic acid motor proteins move along the crowded DNA substrates that are likely to exist in physiological settings. This review summarizes recent progress in understanding how DNA-binding motor proteins respond to the presence of other proteins that lie in their paths. We highlight recent single-molecule biophysical experiments aimed at addressing this question, with an emphasis placed on analyzing the single-molecule, ensemble biochemical, and in vivo data from a mechanistic perspective.

Basic properties of epigenetic systems: lessons from the centromere

Chromatin-based epigenetic inheritance cooperates with cis-acting DNA sequence information to propagate gene expression states and chromosome architecture across cell division cycles. Histone proteins and their modifications are central components of epigenetic systems but how, and to what extent, they are propagated is a matter of continued debate. Centromeric nucleosomes, marked by the histone H3 variant CENP-A, are stable across mitotic divisions and are assembled in a locus specific and cell cycle controlled manner. The mechanism of inheritance of this unique chromatin domain has important implications for how general nucleosome transmission is controlled in space and time.

Modulation of DNA synthesis in Saccharomyces cerevisiae nuclear extract by DNA polymerases and the origin recognition complex

We have analyzed the modulation of DNA synthesis on a supercoiled plasmid DNA template by DNA polymerases (pol), minichromosome maintenance protein complex (Mcm), topoisomerases, and the origin recognition complex (ORC) using an in vitro assay system. Antisera specific against the four-subunit pol alpha, the catalytic subunit of pol delta, and the Mcm467 complex each inhibited DNA synthesis. However, DNA synthesis in this system appeared to be independent of polepsilon. Consequently, DNA synthesis in the in vitro system appeared to depend only on two polymerases, alpha and delta, as well as the Mcm467 DNA helicase. This system requires supercoiled plasmid DNA template and DNA synthesis absolutely required DNA topoisomerase I. In addition, we also report here a novel finding that purified recombinant six subunit ORC significantly stimulated the DNA synthesis on a supercoiled plasmid DNA template containing an autonomously replicating sequence, ARS1.

Ultraviolet radiation sensitivity and reduction of telomeric silencing in Saccharomyces cerevisiae cells lacking chromatin assembly factor-I

In vivo, nucleosomes are formed rapidly on newly synthesized DNA after polymerase passage. Previously, a protein complex from human cells, termed chromatin assembly factor-I (CAF-I), was isolated that assembles nucleosomes preferentially onto SV40 DNA templates that undergo replication in vitro. Using a similar assay, we now report the purification of CAF-I from the budding yeast Saccharomyces cerevisiae. Amino acid sequence data from purified yeast CAF-I led to identification of the genes encoding each subunit in the yeast genome data base. The CAC1 and CAC2 (chromatin assembly complex) genes encode proteins similar to the p150 and p60 subunits of human CAF-I, respectively. The gene encoding the p50 subunit of yeast CAF-I (CAC3) is similar to the human p48 CAF-I subunit and was identified previously as MSI1, a member of a highly conserved subfamily of WD repeat proteins implicated in histone function in several organisms. Thus, CAF-I has been conserved functionally and structurally from yeast to human cells. Genes encoding the CAF-I subunits (collectively referred to as CAC genes) are not essential for cell viability. However, deletion of any CAC gene causes an increase in sensitivity to ultraviolet radiation, without significantly increasing sensitivity to gamma rays. This is consistent with previous biochemical data demonstrating the ability of CAF-I to assemble nucleosomes on templates undergoing nucleotide excision repair. Deletion of CAC genes also strongly reduces silencing of genes adjacent to telomeric DNA; the CAC1 gene is identical to RLF2 (Rap1p localization factor-2), a gene required for the normal distribution of the telomere-binding Rap1p protein within the nucleus. Together, these data suggest that CAF-I plays a role in generating chromatin structures in vivo.

Nucleosome assembly by a complex of CAF-1 and acetylated histones H3/H4

Chromatin assembly factor 1 (CAF-1) assembles nucleosomes in a replication-dependent manner. The small subunit of CAF-1 (p48) is a member of a highly conserved subfamily of WD-repeat proteins. There are at least two members of this subfamily in both human (p46 and p48) and yeast cells (Hat2p, a subunit of the B-type H4 acetyltransferase, and Msi1p). Human p48 can bind to histone H4 in the absence of CAF-1 p150 and p60. p48, also a known subunit of a histone deacetylase, copurifies with a chromatin assembly complex (CAC), which contains the three subunits of CAF-1 (p150, p60, p48) and H3 and H4, and promotes DNA replication-dependent chromatin assembly. CAC histone H4 exhibits a novel pattern of lysine acetylation that overlaps with, but is distinct from, that reported for newly synthesized H4 isolated from nascent chromatin. Our data suggest that CAC is a key intermediate of the de novo nucleosome assembly pathway and that the p48 subunit participates in other aspects of histone metabolism.

Expression, purification, and characterization of DNA polymerases involved in papovavirus replication

In recent years, work from a large number of laboratories has greatly expanded our knowledge of the biochemical characteristics and the genetic structure of the DNA polymerases used during papovavirus DNA replication. The development of in vitro DNA replication systems for both SV40 and polyoma virus has been paramount in facilitating the development of the current models describing how DNA polymerase alpha and delta function to replicate the genomes of these two viruses. Our studies have demonstrated that the proteins recognized to be essential for both in vitro SV40 and polyoma viral origin-dependent DNA synthesis can be isolated from cells as an intact complex. We have shown that the human cell MRC closely resembles the murine cell MRC, in both its protein composition and its fractionation and chromatographic profile. In addition, our data regarding both the human and the murine MRC support the dipolymerase model proposed from in vitro DNA replication studies using reconstituted assay systems. In addition, analysis of the nucleotide sequence of the genes encoding DNA polymerase alpha and delta has revealed that the amino acids encoded by several regions of these two genes have been rigorously maintained across evolutionary lines. This information has permitted the identification of protein domains which mediate the complex series of protein-protein interactions that direct the DNA polymerases to the cell nucleus, specify complete or partial exonuclease active sites, and participate in the interaction of each DNA polymerase with the DNA template. Expression studies examining each of the genes encoding DNA polymerase alpha and delta clearly indicate that both DNA polymerases are cell cycle regulated and undergo a dramatic induction in their expression when quiescent cells are stimulated to enter the cell cycle. This is in contrast to the two- to three-fold upregulation in the level of expression of these two genes when cycling cells cross the G1/S boundary. In addition, both proteins are phosphorylated in a cell cycle-dependent manner, and phosphorylation appears to be mediated through the action of a cdc2-dependent protein kinase. Despite all of this new information, much remains to be learned about how papovavirus DNA replication is regulated and how these two DNA polymerases act in vivo to faithfully copy the viral genomes. Studies have yet to be performed which identify all of the cellular factors which potentially mediate papovavirus DNA replication. The reconstituted replication systems have yielded a minimum number of proteins which are required to replicate SV40 and polyoma viral genomes in vitro. However, further studies are needed to identify additional factors which may participate in each step of the initiation, elongation, and termination phases of viral genome replication. As an example, models describing the potential role of cellular helicases, which are components of the MRC isolated from murine and human cells, have yet to be described. It is also conceivable that there are a number of other proteins which serve to attach the MRC to the nuclear matrix, stimulate viral DNA replication, and potentially regulate various aspects of the activity of the MRC throughout viral DNA replication. We are currently working toward characterizing the biochemical composition of the MRC from both murine and human cells. Our goals are to identify all of the structural components of the MRC and to define the role of these components in regulating papovavirus and cellular DNA replication. We have also begun studies to visualize the spatial organization of these protein components within the MRC, examine the regulatory processes controlling the activity of the various components of the MRC, and then develop this information into a coherent picture of the higher order structure of the MRC within the cell nucleus. We believe that this information will enable us to develop an accurate view of the detailed processes mediating both pa

Further characterization of the human cell multiprotein DNA replication complex

Evidence for multiprotein complexes playing a role in DNA replication has been growing over the years. We have previously reported on a replication-competent multiprotein form of DNA polymerase isolated from human (HeLa) cell extracts. The proteins that were found at that time to co-purify with the human cell multiprotein form of DNA polymerase included: DNA polymerase alpha, DNA primase, topoisomerase I, RNase H, PCNA, and a DNA-dependent ATPase. The multiprotein form of the human cell DNA polymerase was further purified by Q-Sepharose chromatography followed by glycerol gradient sedimentation and was shown to be fully competent to support origin-specific and large T-antigen dependent simian virus 40 (SV40) DNA replication in vitro [Malkas et al. (1990b): Biochemistry 29:6362-6374]. In this report we describe the further characterization of the human cell replication-competent multiprotein form of DNA polymerase designated MRC. Several additional DNA replication proteins that co-purify with the MRC have been identified. These proteins include: DNA polymerase delta, RF-C, topoisomerase II, DNA ligase I, DNA helicase, and RP-A. The replication requirements, replication initiation kinetics, and the ability of the MRC to utilize minichromosome structures for DNA synthesis have been determined. We also report on the results of experiments to determine whether nucleotide metabolism enzymes co-purify with the human cell MRC. We recently proposed a model to represent the MRC that was isolated from murine cells [Wu et al. (1994): J Cell Biochem 54:32-46]. We can now extend this model to include the human cell MRC based on the fractionation, chromatographic and sedimentation behavior of the human cell DNA replication proteins. A full description of the model is discussed. Our experimental results provide further evidence to suggest that DNA synthesis is mediated by a multiprotein complex in mammalian cells.

Assembly of nucleosomes: do multiple assembly factors mean multiple mechanisms?

In eukaryotic cells, transcription and DNA replication occur on DNA templates associated with chromatin proteins, most notably histone octamers. Protein factors that can assemble these units have been isolated from many sources. In particular, one factor from human cells is associated with ongoing DNA synthesis; other known assembly factors are not obligately coupled to the replication process. The wide variety of histone chaperones suggests that multiple pathways for the remodeling of chromatin structure have evolved.

Cloning of the mouse cDNA encoding DNA topoisomerase I and chromosomal location of the gene

The mouse cDNA encoding DNA topoisomerase I (TopoI) was cloned and the nucleotide sequence of 3512 bp was determined. The cDNA clone contained an open reading frame encoding a protein of 767 amino acids (aa), which is 2 aa longer than its human counterpart. Overall aa sequence homology between the mouse and human, and between the mouse and yeast (Saccharomyces cerevisiae) sequences was 96% and 42%, respectively. The mouse TopI gene was mapped at position 54.5 on chromosome 2 from linkage analyses of a three-point cross test with Geg, Ada, and a as marker genes.

Replication of SV40 minichromosomes in vitro

We operationally define two forms of SV40 minichromosomes, a 75S-form, prepared at low salt concentration, referred to as native minichromosomes, and a 50S-form, obtained after treatment with 0.5 M potassium acetate, the salt-treated minichromosomes. Both preparations of minichromosomes serve well as templates for replication in vitro. Their respective replication products are strikingly different: replicated native minichromosomes contain a densely packed array of the maximal number of nucleosomes whereas replicated salt-treated minichromosomes carry, on average, half of the maximal number. We conclude that in both cases parental nucleosomes are transferred to progeny DNA, and, in addition, that an assembly of new nucleosomes occurs during the replication of native minichromosomes. This is apparently due to the presence of a nucleosome assembly factor as a constituent of native minichromosomes that dissociates upon treatment with salt. We further show that preparations of minichromosomes usually contain significant amounts of copurifying hnRNP particles and SV40 virion precursor particles. However, these structures do not detectably affect the replication and the chromatin assembly reactions.

Characterization of a camptothecin-resistant human DNA topoisomerase I in an in vitro system for Simian virus 40 DNA replication

DNA topoisomerase I was required for bidirectional DNA replication in an in vitro system for Simian virus 40 (SV40) DNA replication with purified proteins in which the replication fork moved at the rate of 260 nucleotides/min on average. DNA topoisomerase I purified from camptothecin-resistant human lymphoblastoid cells, which confers high resistance of cellular DNA replication to camptothecin [Andoh, T., Ishii, K., Suzuki, Y., Ikegami, Y., Kusunoki, Y., Takemoto, Y. & Okada, K. (1987) Proc. Natl Acad. Sci. USA 84, 5565-5569], was characterized using this system. The activity of stimulating bidirectional DNA replication was comparable between two topoisomerase I from parental and resistant cells, i.e. in its dose-response relationship and in its time course for DNA synthesis. Camptothecin severely inhibited the leading as well as the lagging strand synthesis in the reaction containing the wild type topoisomerase I but not the mutant type topoisomerase I. The mutant type topoisomerase I was over 125-fold as resistant to camptothecin as the wild type topoisomerase I. These results are in good agreement with those on the sensitivity of cellular DNA synthesis to camptothecin in the resistant cells. These findings suggest that topoisomerase I is involved in cellular DNA replication as a swivelase and the mutation conferring camptothecin-resistance on the enzyme does not affect its functional efficiency in this system.