Replicative intermediates in UV-irradiated simian virus 40

We have used Simian virus 40 (SV40) as a probe to study the replication of UV-damaged DNA in mammalian cells. Viral DNA replication in infected monkey kidney cells was synchronized by incubating a mutant of SV40 (tsA58) temperature-sensitive for the initiation of DNA synthesis at the restrictive temperature and then adding aphidicolin to temporarily inhibit DNA synthesis at the permissive temperature while permitting pre-replicative events to occur. After removal of the drug, the infected cells were irradiated at 100 J/m2 (254 nm) to produce 6-7 pyrimidine dimers per SV40 genome, and returned to the restrictive temperature to prevent reinitiation of replication from the SV40 origin. Replicative intermediates (RI) were labeled with [3H]thymidine, and isolated by centrifugation in CsCl/ethidium bromide gradients followed by BND-cellulose chromatography. The size distribution of daughter DNA strands in RI isolated shortly after irradiation was skewed towards lengths less than the interdimer spacing in parental DNA; this bias persisted for at least 1 h after irradiation, but disappeared within 3 h, by which time the size of the newly-synthesized DNA exceeded the interdimer distance. No significant excision of dimers from parental strands in either replicative intermediates or Form I (closed circular) DNA molecules was detected. These data are consistent with the hypothesis that replication forks are temporarily blocked by dimers encountered on the leading strand side of the fork, but that daughter strand continuity opposite dimers is eventually established. Evidence was obtained for the generation at late times after irradiation, of Form I molecules in which the daughter DNA strands contain dimers. Thus DNA strand exchange as well as trans-dimer synthesis may be involved in the generation of supercoiled Form I DNA from UV-damaged SV40 replicative intermediates.     

Native replication intermediates of the yeast 20 S RNA virus have a single-stranded RNA backbone

20 S RNA virus is a positive strand RNA virus found in Saccharomyces cerevisiae. The viral genome (2.5 kb) only encodes its RNA polymerase (p91) and forms a ribonucleoprotein complex with p91 in vivo. A lysate prepared from 20 S RNA-induced cells showed an RNA polymerase activity that synthesized the positive strands of viral genome. When in vitro products, after phenol extraction, were analyzed in a time course, radioactive nucleotides were first incorporated into double-stranded RNA (dsRNA) intermediates and then chased out to the final single-stranded RNA products. The positive and negative strands in these dsRNA intermediates were non-covalently associated, and the release of the positive strand products from the intermediates required a net RNA synthesis. We found, however, that these dsRNA intermediates were an artifact caused by phenol extraction. Native replication intermediates had a single-stranded RNA backbone as judged by RNase sensitivity experiments, and they migrated distinctly from a dsRNA form in non-denaturing gels. Upon completion of RNA synthesis, positive strand RNA products as well as negative strand templates were released from replication intermediates. These results indicate that the native replication intermediates consist of a positive strand of less than unit length and a negative strand template loosely associated, probably through the RNA polymerase p91. Therefore, W, a dsRNA form of 20 S RNA that accumulates in yeast cells grown at 37 degrees C, is not an intermediate in the 20 S RNA replication cycle, but a by-product.     

Transcriptional organization of the Drosophila melanogaster ribosomal RNA genes.

Five distinct DNA replicating intermediates have been separated from lysates of bacteriophage G4-infected cells pulse-labelled during the period of replicative form synthesis using propidium diiodide/caesium chloride gradients. These are a partially single-stranded theta structure that is labelled in both the viral and complementary DNA strands; partially single-stranded circles, some with an unfinished viral DNA strand (25%) and some with an unfinished complementary DNA strand (75%); replicative form II(RFII) and replicative form I(RFI) DNA labelled only in the complementary DNA strand. To explain the pulse-label data a model is proposed in which G4 replicative form replication takes place by a displacement mechanism in which synthesis of the new viral DNA strand displaces the old viral DNA strand as a single-stranded DNA loop (D-loop) and when the displacement reaches half way round the molecule (the origin of synthesis of the G4 viral and complementary DNA strands are on opposite sides of the genome, Martin &; Godson 1977) synthesis of the complementary DNA strand starts, but in the opposite direction. Strand separation of the parent helix runs ahead of DNA synthesis, releasing two partially single-stranded circles from the replicating structure which then complete their replication as free single-stranded DNA circles. No evidence was found to support a rolling circle displacement mechanism of G4 replicative form synthesis.     

Structure of F-actin needles from extracts of sea urchin oocytes

The mouse L-cell line LD maintains its mitochondrial DNA genome in the form of a head-to-tail unicircular dimer of the monomeric 16,000 base-pair species. This situation permits a comparison of the mechanism of replication of this dimeric molecule with our previous studies of replication of monomeric mouse L-cell mitochondrial DNA. Whereas monomeric mitochondrial DNA requires about one hour for a round of replication, the dimeric molecule requires almost three hours. Denaturing agarose gel electrophoretic analyses of replicative intermediates reveals several discrete size classes of partially replicated daughter strands of dimeric mitochondrial DNA. This suggests that replication occurs with specific discontinuities in the rate of daughter strand synthesis. The strand specificity of these daughter strands was determined by hybridization with ³²P-labeled DNA representing either the heavy or light strand mitochondrial DNA sequence. The sizes and strand specificities of these discrete daughter strands indicate that the same set of control sequences is functional in both dimer and monomer mitochondrial DNA replication.Immediately following a round of replication, the majority of dimeric mitochondrial DNA molecules contain displacement loops, as assessed by their sensitivity to nicking within the displaced DNA strand by single-strand DNA specific S₁ nuclease under conditions which leave supercoiled DNA intact. This result is in contrast with the conformation of newly replicated monomeric mitochondrial DNA molecules, which lack both superhelical turns and displacement loops. This indicates that dimeric mitochondrial DNA proceeds through a different series of post-replicative processing steps than does monomeric mitochondrial DNA. We postulate that intermediates at late stages of dimeric mitochondrial DNA replication contain displacement loops which remain intact following closure of the full-length daughter strands.     

Replication of the cauliflower mosaic virus: role and stability of the cloned delta 3 discontinuity sequence

A fragment of cauliflower mosaic virus (CaMV) DNA, containing delta 3, one of the three discontinuity sequences, was cloned in various ways into CaMV DNA deleted for the delta 3 sequence. The series of constructions was monitored for the appearance of the typical single-strand (ss) discontinuity after hybrid CaMV replication in plants. The delta 3 discontinuity was observed only if the orientation of inserted DNA sequence was the same as in the wild-type virus. Long polylinker sequences used for insertion of the fragment into cloned viral DNA, affected the stability of the insert in progeny viral DNA in plants by acting as recombination targets.     

Characterisation of cauliflower mosaic virus DNA forms isolated from infected turnip leaves.

Several different forms of cauliflower mosaic virus (CaMV) DNA were detected in nucleic acid preparations from CaMV-infected turnip leaves. As well as supercoiled and open-circular molecules, various linear DNA structures were identified. The relative amounts of these DNA forms varied in plants infected with different CaMV isolates. Restriction enzyme mapping and one- and two-dimensional gel electrophoresis revealed the presence of linear molecules apparently formed by breaks in the second strand at each of the three discontinuities. Two major linear DNA forms are double-stranded over part of their length and appear to have single-stranded extensions of the -strand of variable length. Since these DNA forms are not produced during extraction and probably exist as unencapsidated or partially encapsidated molecules, they may represent intermediates either in DNA replication or in virion assembly.     

Exposure to camptothecin breaks leading and lagging strand simian virus 40 DNA replication forks

To better understand aberrant simian virus 40 DNA replication intermediates produced by exposure of infected cells to the anticancer drug camptothecin, we compared them to forms produced by S1 nuclease digestion of normal viral replication intermediates. All of the major forms were identical in both cases. Thus the aberrant viral replicating forms in camptothecin-treated cells result from DNA strand breaks at replication forks. Linear simian virus 40 forms which are produced by camptothecin exposure during viral replication were identified as detached DNA replication bubbles. This indicates that double strand DNA breaks caused by camptothecin-topoisomerase I complexes occur at both leading and lagging strand replication forks in vivo.     

Coexistence of nucleosomal and various non-nucleosomal chromatin configurations in cells infected with herpes simplex virus

Coexistence of four different forms of chromatin was observed by electron microscopy in nuclear spread preparations of monkey kidney cells during late stages of infection with herpes simplex virus (HSV-1 AMG). Besides typical nucleosomal (i) chromatin, thin (3-5 nm) strands morphologically indistinguishable from protein-free DNA were frequent, without (ii) or with (iii) sparse 10-22 nm large granules different from nucleosomes. In addition, uniformly thick (mean 17 nm), heavily stained chromatin strands (iv) were seen. The non-nucleosomal character of types (iii) and (iv) chromatin was also demonstrated by their resistance to histone removal in Sarkosyl and heparin. All four forms were seen in capsid-associated HSV-DNA molecules, and various combinations of these forms occurred in adjacent regions of the same DNA molecule, including the vicinity of replication branch points. Especially frequent were regions of chromatin types (ii) or (iii) alternating with thickly coated intercepts of type (iv) chromatin, the latter often displaying "bubble"-like strand separations. The appearance of chromatin types (ii)-(iv) was dependent on viral replication. These chromatin arrays were compared with structures observed in purified HSV-DNA from these cells. Patterns of single-stranded regions were found in HSV-DNA that were similar to those observed in the thickly coated type (iv) chromatin. It is concluded that, in these nuclei, non-nucleosomal arrangements can be formed, at least on viral DNA, under conditions of continued DNA synthesis and inhibited protein synthesis, and that single-stranded DNA is packed into a characteristic thick strand of non-nucleosomal chromatin by association with a special, probably virus-coded protein.     

The termination region for SV40 DNA replication directs the mode of separation for the two sibling molecules

Separation of the two newly replicated chromosomes in simian virus 40 late replicating intermediates (RI*) occurred by two pathways. The parental DNA strands were completely unwound, releasing circular DNA monomers with a gap in the nascent strand (Form II*), or duplex DNA in the termination region was not unwound, resulting in formation of catenated dimers. Under optimal conditions, both products were transient intermediates in replication, although Form II* was predominant. However, in hypertonic medium both RI* and catenated dimers accumulated, and Form II* was not observed. Hypertonic medium appeared to inhibit both DNA unwinding in the termination region and separation of catenated dimers. When the size of the genome or the position of the origin of replication was changed, termination occurred at sites other than that of wild-type SV40. Neither catenated dimers nor RI* DNA accumulated at these sites. Instead, RI* separated into Form II*. Unwinding parental DNA was more difficult at some termination regions than others. Therefore, although completion of DNA replication does not require a unique termination sequence, this sequence can determine the mode of separation for sibling molecules.     

In vitro replication of adeno-associated virus DNA: enhancement by extracts from adenovirus-infected HeLa cells.

Previously we have described an in vitro assay for the replication of adeno-associated virus type 2 (AAV2) DNA. Addition of the AAV2 nonstructural protein Rep68 to an extract from uninfected cells supports the replication of linear duplex AAV DNA. In this report, we examine replication of linear duplex AAV DNA in extracts from either uninfected or adenovirus (Ad)-infected HeLa cells. The incorporation of radiolabeled nucleotides into full-length linear AAV DNA is 50-fold greater in extracts from Ad-infected cells than in extracts from uninfected cells. In addition, the majority of the labeled full-length AAV DNA molecules synthesized in the Ad-infected extract have two newly replicated strands, whereas the majority of labeled full-length AAV DNA molecules synthesized in the uninfected extract have only one newly replicated strand. The numbers of replication initiations on original templates in the two assays are approximately the same; however, replication in the case of the Ad-infected cell extract is much more likely to result in the synthesis of a full-length AAV DNA molecule. Most of the newly replicated molecules in the assay using uninfected cell extracts are in the form of stem-loop structures. We hypothesize that Ad infection provides a helper function related to elongation during replication by a single-strand displacement mechanism. In the assay using the uninfected HeLa cell extract, replication frequently stalls before reaching the end of the genome, causing the newly synthesized strand to be displaced from the template, with a consequent folding on itself and replication back through the inverted terminal repeat, using itself as a template. In support of this conjecture, replication in the uninfected cell extract of shorter substrate molecules is more efficient, as measured by incorporation of radiolabeled nucleotides into full-length substrate DNA. In addition, when shorter substrate molecules are used as the template in the uninfected HeLa cell assay, a greater proportion of the labeled full-length substrate molecules contain two newly replicated strands. Shorter substrate molecules have no replicative advantage over full-length substrate molecules in the assay using an extract from Ad-infected cells.     

Viral SPP1 DNA is infectious in naturally competent Bacillus subtilis cells: inter- and intramolecular recombination pathways

A proteolyzed bacteriophage (phage) might release its DNA into the environment. Here, we define the recombination functions required to resurrect an infective lytic phage from inactive environmental viral DNA in naturally competent Bacillus subtilis cells. Using phage SPP1 DNA, a model that accounts for the obtained data is proposed (i) the DNA uptake apparatus takes up environmental SPP1 DNA, fragments it, and incorporates into the cytosol different linear single-stranded (ss) DNA molecules shorter than genome-length; (ii) the SsbA-DprA mediator loads RecA onto any fragmented linear SPP1 ssDNA, but negative modulators (RecX and RecU) promote a net RecA disassembly from these ssDNAs not homologous to the host genome; (iii) single strand annealing (SSA) proteins, DprA and RecO, anneal the SsbA- or SsbB-coated complementary strands, yielding tailed SPP1 duplex intermediates; (iv) RecA polymerized on these tailed intermediates invades a homologous region in another incomplete molecule, and in concert with RecD2 helicase, reconstitutes a complete linear phage genome with redundant regions at the ends of the molecule; and (v) DprA, RecO or viral G35P SSA, may catalyze the annealing of these terminally redundant regions, alone or with the help of an exonuclease, to produce a circular unit-length duplex viral genome ready to initiate replication.     

Isolation of a fraction from cauliflower mosaic virus-infected protoplasts which is active in the synthesis of (+) and (-) strand viral DNA and reverse transcription of primed RNA templates

Sub-cellular fractions, isolated from cauliflower mosaic virus (CaMV)-infected turnip protoplasts, are capable of synthesising CaMV DNA in vitro on an endogenous template and of reverse transcribing oligo dT-primed cowpea mosaic virus RNA. The activity was not detected in mock-inoculated protoplasts. In vitro-labelled DNA hybridized to single-stranded M13 clones complementary to the putative origins of (-) and (+) strand CaMV DNA synthesis and to restriction endonuclease fragments encompassing more than 90% of the CaMV genome. The synthesis of (-) and (+) strand DNA appeared asymmetric. The template(s) for in vitro CaMV DNA synthesis are in a partially nuclease-resistant form. Fractions capable of in vitro CaMV DNA synthesis contained CaMV RNA both heterogeneous and as discrete species; they also contained a range of different sizes of CaMV DNA. Several lines of evidence indicate that this range of in vitro-labelled CaMV DNA, extending from 0.6kb to 8.0kb in length, represents elongating (-) strand DNA. These are discussed in relation to their role as possible replicative intermediates.     

Mouse mammary tumor virus DNA in infected rat cells: characterization of unintegrated forms.

Mouse mammary tumor virus (MMTV) DNA in chronically infected rat hepatoma cells is maintained in both the integrated and unintegrated state. Fractionation of DNA by the procedure of Hirt (1967) as well as by sedimentation through alkaline sucrose suggests that about two thirds of the viral DNA is associated with high molecular weight cell DNA. The remainder of the viral DNA is unintegrated and is present primarily as linear or open circular duplexes consisting of a genome-length strand complementary to the viral RNA ("minus" strand) and "plus" strands of subgenomic length. Approximately 20% of the unintegrated MMTV DNA is present as double-stranded, covently closed circles (form I) with a molecular weight of 6 X 10(6) daltons. Form I viral DNA is found primarily in the nucleus, whereas the open forms are both nuclear and cytoplasmic.     

Noncanonical DNA elements in the lamin B2 origin of DNA replication

DNA replication origins of eukaryotes lack linear replicator elements but contain short (dT)(n) (dA)(n) sequences that could build mutually equivalent unorthodox structures. Here we report that the lamin B2 origin of DNA replication adopts an alternative form characterized by unpaired regions CTTTTTTTTTTCC/GGAAAAAAAAAAG (3900-3912) and CCTTTTTTTTC/GAAAAAAAAGG (4141-4151). Both unpaired regions are resistant to DNase and except in central parts of their homopyrimidine strands are sensitive to single strand-specific chemicals. Interactions that protect central pyrimidines probably stabilize the bubble-like areas. Because DNA fragments containing either one or both bubbles migrate in TBM (89 mm Tris base, 89 mm boric acid, and 2 mm MgCl(2)) PAGE even faster than expected from their linear size, interacting regions are expected to belong to the same molecule. In an origin fragment containing a single bubble, free homopyrimidine strand can only interact with Hoogsteen hydrogen bonding surfaces from a complementary double stranded sequence. Indeed, this origin fragment reacts with triplex preferring antibody. In competition binding experiments control double stranded DNA or single stranded (dT)(40) do not affect origin-antibody interaction, whereas TAT and GGC triplexes exert competitive effect. Because the chosen fragment does not contain potential GGC forming sequences, these experiments confirm that the lamin B2 origin adopts a structure partly composed of intramolecular TAT triads.     

Initiation of lagging-strand synthesis for pBR322 plasmid DNA replication in vitro is dependent on primosomal protein i encoded by dnaT

The role of the primosome assembly and protein n' recognition site in replication of pBR322 plasmid was examined. The following evidence indicates that the primosome is involved in lagging-strand synthesis of pBR322 plasmid replication in vitro. Early replicative intermediates with newly synthesized leading strand, approximately 1 kilobase pair long, immediately downstream of the replication origin accumulate in products synthesized in extracts from a dnaT strain that lacks primosomal protein i or in wild-type extracts supplemented with anti-protein i antibody. These intermediates are converted efficiently into full-length DNA by addition of purified protein i. Consistent with the previously proposed role of the primosome (Arai, K. and Kornberg, A. (1981) Proc. Natl. Acad. Sci. U. S. A. 78, 69-73), an n' site on the lagging strand, but not on the leading strand, is required for efficient replication of the plasmid in vitro. Plasmids lacking an n' site on the lagging strand replicate only to a limited extent in vitro and early replicative intermediates carrying nascent leading strands are accumulated, although a portion of the intermediates complete replication to yield full-length DNA. The latter reaction is completely inhibited by addition of anti-protein i antibody. Insertion of the n' site of phage phi X174 into pBR322 plasmids lacking lagging-strand n' sites restores the replicative ability of the mutant plasmid comparable to that of the wild-type plasmid. These results indicate that protein i is essential for lagging-strand synthesis of pBR322 plasmid in vitro and that it may play an important role in the priming events as a part of either an n' site-dependent primosome or an n' site-independent, as yet unidentified, priming complex.     

A rolling circle model of the in vivo replication of bacteriophage phiX174 replicative form DNA: different fate of two types of progeny replicative form

In a preceding paper (Schröder and Kaerner, 1972) a rolling circle mechanism has been described for the replication of bacteriophage φX174 replicative form. Replication involved nicking and elongation of the viral (positive) strand component of the RF molecule resulting in the displacement of a single-strand tail of increasing length. The synthesis of the new complementary (negative) strand on the single-strand tails appears to be initiated with considerable delay and converts the tail into double-stranded DNA. Before the new negative strand is completed the replicative intermediates split into (I) a complete RF molecule containing the “old” negative and the new positive strand, and (II) a linear, partially double-stranded “tail” consisting of the complete old positive strand and a fragment of the new negative strand.The present study is concerned with the fate during RF replication of these fragments of the rolling circles. Those RFII molecules containing the old negative strands appear to go into further replication rounds repeatedly. Some of the tails were found in the infected cells in their original linear form. “Gapped” RFII molecules, which have been described earlier by Schekman and co-workers (Schekman &; Ray, 1971; Schekman et al., 1971), are supposed to originate from the tails of rolling circle intermediates by circularization of their positive strand components. Evidence is provided by our experiments that even late during RF replication these gaps are present only in the negative strands of RFII. Appropriate chase experiments indicated that the tails finally are converted to RFI molecules. Progeny RFI molecules could not be observed to start new replication rounds under our conditions although we cannot exclude that this might happen to some minor extent.The results presented suggest that the master templates for RF replication are the first negative strands to be formed, rather than the parental positive strands.