Assembly of SV40 and polyoma minichromosomes during replication

JC polyomavirus: a short review of its biology, its association with progressive multifocal leukoencephalopathy, and the diagnostic value of different methods to manifest its activity or presence

INTRODUCTION

JC polyomavirus is the causative agent of progressive multifocal leukoencephalopathy (PML), a demyelinating disease resulting from the lytic infection of oligodendrocytes that may develop in immunosuppressed individuals: HIV1 infected or individuals under immunosuppressive therapies. Understanding the biology of JCPyV is necessary for a proper patient management, the development of diagnostic tests, and risk stratification.

AREAS COVERED

The review covers different areas of expertise including the genomic characterization of JCPyV strains detected in different body compartments (urine, plasma, and cerebrospinal fluid) of PML patients, viral mutations, molecular diagnostics, viral miRNAs, and disease.

EXPERT OPINION

The implementation of molecular biology techniques improved our understanding of JCPyV biology. Deep sequencing analysis of viral genomes revealed the presence of viral quasispecies in the cerebrospinal fluid of PML patients characterized by noncoding control region rearrangements and VP1 mutations. These neurotropic JCPyV variants present enhanced replication and an altered cell tropism that contribute to PML development. Monitoring these variants may be relevant for the identification of patients at risk of PML. Multiplex realtime PCR targeting both the LTAg and the archetype NCCR could be used to identify them. Failure to amplify NCCR should indicate the presence of a JCPyV prototype speeding up the diagnostic process.

Chromatin replication and epigenetic cell memory

Propagation of the chromatin landscape across cell divisions is central to epigenetic cell memory. Mechanistic analysis of the interplay between DNA replication, the cell cycle, and the epigenome has provided insights into replication-coupled chromatin assembly and post-replicative chromatin maintenance. These breakthroughs are critical for defining how proliferation impacts the epigenome during cell identity changes in development and disease. Here we review these findings in the broader context of epigenetic inheritance across mitotic cell division.

The Fork in the Road: Histone Partitioning During DNA Replication

In the following discussion the distribution of histones at the replication fork is examined, with specific attention paid to the question of H3/H4 tetramer "splitting." After a presentation of early experiments surrounding this topic, more recent contributions are detailed. The implications of these findings with respect to the transmission of histone modifications and epigenetic models are also addressed.

Assembling chromatin: the long and winding road

It has been over 35 years since the acceptance of the "chromatin subunit" hypothesis, and the recognition that nucleosomes are the fundamental repeating units of chromatin fibers. Major subjects of inquiry in the intervening years have included the steps involved in chromatin assembly, and the chaperones that escort histones to DNA. The following commentary offers an historical perspective on inquiries into the processes by which nucleosomes are assembled on replicating and nonreplicating chromatin. This article is part of a Special Issue entitled: Histone chaperones and Chromatin assembly.

Chromatin as a potential carrier of heritable information

Organisms with the same genome can inherit information in addition to that encoded in the DNA sequence-this is known as epigenetic inheritance. Epigenetic inheritance is responsible for many of the phenotypic differences between different cell types in multicellular organisms. Work by many investigators over the past decades has suggested that a great deal of epigenetic information might be carried in the pattern of post-translational modifications of the histone proteins, although this is not as well established as many believe. For example, it is unclear whether and how the histones, which are displaced from the chromosome during passage of the replication fork and are often exchanged from the DNA template at other times, carry information from one cellular generation to the next. Here, we briefly review the evidence that some chromatin states are indeed heritable, and then focus on the mechanistic challenges that remain in order to understand how this inheritance can be achieved.

Parental nucleosomes segregated to newly replicated chromatin are underacetylated relative to those assembled de novo

Antibodies specific for acetylated histone H4 were used to examine the acetylation state of parental histones that segregate to newly replicated DNA. To generate newly replicated chromatin containing only segregated parental nucleosomes, isolated nuclei were labeled with [3H]TTP in vitro; alternatively, whole cells were labeled with [3H]thymidine in the presence of cycloheximide. Soluble chromatin was prepared by micrococcal nuclease digestion, and subjected to immunoprecipitation with "penta" antibodies (Lin et al., 1989). In sharp contrast to nucleosomes containing newly synthesized, diacetylated H4 (Perry et al., 1993), chromatin replicated in vitro was only marginally susceptible to immunoprecipitation. Control experiments established that bona fide acetylated chromatin was selectively immunoprecipitated by the same techniques and that segregated nucleosomes were not disassembled during treatment with "penta" antibodies. When replication was coupled to an in vitro histone acetylation system, the enrichment for segregated nucleosomes in the immunopellet increased approximately 3-fold, demonstrating that changes in the acetylation state of segregated histones can be detected immunologically and that parental histones on new DNA are accessible to acetyltransferases during, or immediately after, DNA replication. In vivo pulse-chase experiments, performed in the presence of cycloheximide, confirmed these results. Uptake experiments further established that concurrent histone acetylation did not alter the rate of DNA synthesis in vitro. Our results provide evidence that replication-competent chromatin is not obligatorily acetylated, and indicate that the acetylation status of segregated histones may be maintained during chromatin replication. The possible significance of this, with respect to the regulation of chromatin higher order structures during DNA replication, and the propagation of transcriptionally active vs inactive chromatin structures, is discussed.

Histones H1 and H4 are present near the replication fork

The presence of histones H1 and H4 at the sites of actual DNA synthesis has been studied with Ehrlich ascites tumour cells, pulse labeled for different times with 3H-thymidine and then treated with formaldehyde to crosslink histones to DNA. The fixed chromatin fragments were sonicated to reduce the size of DNA, purified in a CsCl gradient and immunoprecipitated with antibodies to histones H1 and H4. Determination of specific radioactivity in precipitated probes showed that both histones have been associated with nascent DNA even upon 1 min pulse with 3H-thymidine, thus indicating their presence near the replication fork.

Differential DNase I sensitivity of the two complementary nucleosomal DNA strands in cycloheximide-treated Ehrlich ascites tumor cells

The accessibility of the two complementary DNA strands in newly replicated chromatin of Ehrlich ascites tumor (EAT) cells grown under conditions of cycloheximide-inhibited protein synthesis was studied by analysis of the DNase I digestion of isolated nuclei. Bulk DNA was labeled with 14C-thymidine and the newly synthesized strands - with bromodeoxyuridine and 3H-thymidine. The DNase I digests were fractionated in two successive CsCl density gradient centrifugations to obtain a dense fraction containing 15-20% newly replicated DNA. Analysis of the distribution of 14C-labeled parental DNA fragments complementary to the 3H-nascent strand has shown that the 14C-labeled fragments prevail in the region of 30-50 nucleotides. Simulation experiments using the rate constants for DNase I attack show that this result may be explained by an enhanced accessibility at the nucleosomal 5'-end region of the parental strands, where the H2a-H2b dimer interacts with DNA. This asymmetry seems to be induced by interactions in the chromatin.

Presence of nucleosomes within irregularly cleaved fragments of newly replicated chromatin

In previous reports (Annunziato et al., J. Biol. Chem., 256:11880-11886 [1981]; Annunziato and Seale, Biochemistry 21:5431-5438 [1982]) we have described two classes of newly replicated chromatin which differ in structure, solubility properties, and requirements for maturation. One class is nucleosomal, soluble at low to intermediate ionic strengths, and acquires mature nucleosomal composition and normal repeat length in the absence of concurrent protein synthesis. In contrast, the other class is cleaved irregularly by MNase (appearing as a smear in DNA gels), is insoluble at moderate ionic strengths, requires protein synthesis to gain normal subunit structure, and comprises approximately 60% of total new chromatin DNA after mild nuclease digestion. It is now demonstrated that this heterogeneous component (produced by the action of either MNase or Hae III on chromatin replicated in cycloheximide) yields nucleosomes when redigested with MNase. The presence of nucleosomes within heterogeneous chromatin fragments suggests that nucleosomal and non-nucleosomal regions may be juxtaposed during chromatin replication. These findings are discussed with respect to current models of nucleosome segregation.

Chromatin assembled in the presence of cytosine arabinoside has a short nucleosome repeat

Incubation of MSB cells with cytosine arabinoside (1-beta-D-arabinofuranosylcytosine, ara-C) inhibits 3H-thymidine incorporation into nascent DNA while nucleosome core histone synthesis proceeds in molar stoichiometry at about 20% of control rates. The excess nascent histone is incorporated into chromatin and nucleosome cores are assembled normally on the small amount of DNA which is synthesized at submaximal levels of ara-C. This DNA becomes packaged into a shortened nucleosome repeat, however. These results indicate that the nucleosome core is a strongly conserved unit of chromatin replication and suggest that the stoichiometry of nascent histone to DNA may be one factor influencing the establishment of the nucleosome repeat length. It cannot be the only factor, however, since the closely packed nucleosomes made in the presence of ara-C begin to return to their normal spacing within six hours after reversal.

Stability of the conservative mode of nucleosome assembly

The conservative assembly of nucleosome histone octamer cores has been confirmed by electrophoretic analysis of density labeled histones following equilibrium buoyant density centrifugation. After normal replication, crosslinked octamers are shown not to contain a mixture of new and old core histones. Moreover, when DNA synthesis is inhibited by ara-C nucleosome cores are still assembled exclusively from nascent histone. Similarly, after release from cycloheximide inhibition newly synthesized core histone is conservatively deposited. Thus, a conservative mechanism of histone octamer assembly occurs when nascent histone is present in the normal stoichiometry to nascent DNA and when chromatin is assembled in nascent histone or nascent DNA excess.

Structure of chromatin at deoxyribonucleic acid replication forks: prenucleosomal deoxyribonucleic acid is rapidly excised from replicating simian virus 40 chromosomes by micrococcal nuclease

Replicating simian virus 40 (SV40) chromosomes were found to be similar to other eukaryotic chromosomes in that the rate and extent of micrococcal nuclease (MNase) digestion were greater with replicating than with nonreplicating mature SV40 chromatin. MNase digestion of replicating SV40 chromosomes, pulse labeled in either intact cells or nuclear extracts, resulted in the rapid release of nascent DNA as essentially bare fragments of duplex DNA (3-7S) that had an average length of 120 base pairs and were degraded during the course of the reaction. In addition, nucleosomal monomers, equivalent in size to those from mature chromosomes, were released. On the other hand, MNase digestion of uniformly labeled mature SV40 chromosomes resulted in the release of only nucleosomal monomers and oligomers. The small nascent DNA fragments released from replicating chromosomes represented prenucleosomal DNA (PN-DNA) from the region of replication forks that encompasses the actual sites of DNA synthesis and includes Okazaki fragments. Predigestion of replicating SV40 chromosomes with both Escherichia coli exonuclease III (3'-5') and bacteriophage T7 gene 6 exonuclease (5'-3') resulted in complete degradation of PN-DNA. This result, together with the observation that isolated PN-DNA annealed equally well to both strands of SV40 restriction fragments, demonstrated that PN-DNA originates from both sides of replication forks. Over 90% of isolated Okazaki fragments annealed only to the retrograde DNA template. The characteristics of isolated PN-DNA were assessed by examining its sensitivity to MNase and single strand specific S1 endonuclease, sedimentation behavior before and after deproteinization, buoyant density in CsCl after formaldehyde treatment, and size on agarose gels. In addition, it was observed that MNase digestion of purified SV40 DNA also resulted in the release of a transient intermediate similar in size to PN-DNA, indicating that a DNA-protein complex is not required to account for the appearance of PN-DNA. These and other data provide a model of replicating chromosomes in which DNA synthesis occurs on a region of replication forks that is free of nucleosomes and is designated as prenucleosomal DNA.

Two-dimensional analysis of proteins sedimenting with simian virus 40 chromosomes

The nonhistone proteins sedimenting in low-salt glycerol gradients with simian virus 40 chromosomes were analyzed by two-dimensional gel electrophoresis, utilizing nonequilibrium pH gradients as the first dimension and sodium dodecyl sulfate-gel electrophoresis as the second dimension. By densitometric quantitation of the radiolabeled proteins present in each fraction of the gradients, it was possible to identify sedimenting with all or a fraction of the simian virus 40 chromosomes. VP-1 sedimented with simian virus 40 chromosomes; additional evidence for its binding to chromosomes was obtained by immunochemical techniques. Four proteins (Mr 25,000, pI 6.0; Mr 32,000, pI 7.2; Mr 35,000, pI 8.5; and Mr 80,000, pI 7.2) sedimented with specific subsets of chromosomes.

Analysis of binding interactions between histone core complex and simian virus 40 DNA. A comparison of acetylated versus non-acetylated histone core complexes

The interactions of acetylated and non-acetylated core complex histones with simian virus 40 (SV40) DNA 1 have been analyzed. A modified filter-binding assay utilizing micrococcal nuclease, which allows quantification of histone octamer binding to DNA has been developed. Using this assay it was determined that both non-acetylated core complex histones ad core complex histones acetylated with acetyl adenylate to levels existing in vivo bind cooperatively to SV40 DNA 1. Although both interactions are cooperative, the magnitude of the cooperativity parameter, omega, is significantly less in the acetylated case. This difference in cooperativity is in contrast to the nearly identical intrinsic association constant, K, observed in both cases.