DNA sequences required for the in vitro replication of adenovirus DNA

An alternative to the adenovirus inverted terminal repeat sequence increases the viral genome replication rate and provides a selective advantage in vitro

During the development of human adenovirus 35-derived replication-incompetent (rAd35) vaccine vectors for prevention of infectious diseases, we detected mutations in the terminal 8 nt of the inverted terminal repeats (ITRs) of rAd35. The switch from the plasmid-encoded sequence 5'-CATCATCA-3' to the alternative sequence 5'-CTATCTAT-3' in the ITRs was found to be a general in vitro propagation phenomenon, as shown for several vectors carrying different transgenes or being derived from different adenovirus serotypes. In each tested case, the plasmid-encoded ITR sequence changed to exactly the same alternative ITR sequence, 5'-CTATCTAT-3'. The outgrowth of this alternative ITR version should result from a growth advantage conferred by the alternative ITR sequence. Indeed, replication kinetics studies of rAd35 harbouring either the original or alternative ITR sequence confirmed an increase in replication speed for rAd35 vectors with the alternative ITR sequence. These findings can be applied to generate recombinant adenoviral vectors harbouring the alternative ITR sequence, which will facilitate the generation of genetically homogeneous seed virus batches. Moreover, vector production may be accelerated by taking advantage of the observed improved replication kinetics associated with the alternative ITR sequence.

Relaxed template specificity in fowl adenovirus 1 DNA replication initiation

The fowl adenovirus 1 (FAdV-1) isolates PHELPS and OTE are highly similar, but have striking differences in the repeat region of the inverted terminal repeat (ITR). Whilst the repeat region in OTE conforms to the conventional human adenovirus repeat region (5'-CATCATC), that of PHELPS contains guanidine residues at positions 1, 4 and 7 (5'-GATGATG). This implies that the FAdV-1 isolates PHELPS and OTE have either distinct template specificity at replication initiation or, alternatively, a relaxed specificity for replication initiation. In this study, the distinct sequence variation at the origin of DNA replication in the ITRs of the FAdV-1 PHELPS and OTE isolates was confirmed. Sequence analyses of the pTP and Pol genes of both PHELPS and OTE did not reveal differences that could explain the distinct template specificity. Replication assays demonstrated that linear DNA fragments flanked by either 5'-CATCATC or 5'-GATGATG termini replicated in cells upon infection with FAdV-1 OTE and FAdV-1 PHELPS. This was evident from the appearance of DpnI-resistant fragments in a minireplicon assay. From these data, it is concluded that FAdV-1 has relaxed, rather than changed, its template specificity at replication initiation.

Adenovirus DNA replication

Replication of the adenovirus genome is catalysed by adenovirus DNA polymerase in which the adenovirus preterminal protein acts as a protein primer. DNA polymerase and preterminal protein form a heterodimer which, in the presence of the cellular transcription factors NFI/CTFI and NFIII/Oct-1, binds to the origin of DNA replication. DNA replication is initiated by DNA polymerase mediated transfer of dCMP onto preterminal protein. Further DNA synthesis is catalysed by DNA polymerase in a strand displacement mechanism which also requires adenovirus DNA binding protein. Here, we discuss the role of individual proteins in this process as revealed by biochemical analysis, mutagenesis and molecular modelling.

Physical interaction of tumour suppressor p53/p73 with CCAAT-binding transcription factor 2 (CTF2) and differential regulation of human high-mobility group 1 (HMG1) gene expression

The CCAAT-binding transcription factor (CTF)/nuclear factor I (NF-I) group of cellular DNA-binding proteins recognizes the sequence GCCAAT and is implicated in eukaryotic transcription, as well as DNA replication. Molecular analysis of human CTF/NF-I cDNA clones revealed multiple mRNA species that contain alternative coding regions, apparently as a result of differential splicing. Expression and functional analysis established that individual gene products can bind to GCCAAT recognition sites and serve as both promoter-selective transcriptional activators and initiation factors for DNA replication. The interaction between CTF2 and p53/p73 was shown to modulate their ability to regulate transcription of their respective target genes. In the present paper, we report that p53 down-regulates the activity of the high mobility group 1 (HMG1) gene promoter, whereas p73alpha up-regulates the activity of this promoter. Furthermore, CTF2 transactivates p53-induced p21 promoter activity, but inhibits p73alpha-induced p21 promoter activity. Using deletion mutants, we found that the DNA-binding domains of both p53 and p73alpha are required for physical interaction with CTF2 via the regions between amino acid residues 161 and 223, and 228 and 312 respectively. CTF2 enhances the DNA-binding activity of p53 and inhibits the DNA-binding activity of p73alpha. These results provide novel information on the functional interplay between CTF2 and p53/p73 as important determinants of their function in cell proliferation, apoptosis, DNA repair and cisplatin resistance.

The origin recognition complex marks a replication origin in the human TOP1 gene promoter

The locations of the origin recognition complex (ORC) in mammalian genomes have been elusive. We have therefore analyzed the DNA sequences associated with human ORC via in vivo cross-linking and chromatin immunoprecipitation. Antibodies specific for hOrc2 protein precipitate chromatin fragments that also contain other ORC proteins, suggesting that the proteins form multisubunit complexes on chromatin in vivo. A binding region for ORC was identified at the CpG island upstream of the human TOP1 gene. Nascent strand abundance assays show that the ORC binding region coincides with an origin of bidirectional replication. The TOP1 gene includes two well characterized matrix attachment regions. The matrix attachment region elements analyzed contain no ORC and constitute no sites for replication initiation. In initial attempts to use the chromatin immunoprecipitation technique for the identification of additional ORC sites in the human genome, we isolated a sequence close to another actively transcribed gene (TOM1) and an alphoid satellite sequence that underlies centromeric heterochromatin. Nascent strand abundance assays gave no indication that the heterochromatin sequence serves as a replication initiation site, suggesting that an ORC on this site may perform functions other than replication initiation.

Purification of a heteromeric CCAAT binding protein from Neurospora crassa

Expression of the Neurospora crassa am (NADP-specific glutamate dehydrogenase) gene is controlled by two upstream enhancer-like elements designated URSam alpha and URSam beta. URSam alpha is localized between - 1.3 and - 1.4 kb with respect to the major transcriptional start site. Deletion of a 90 bp sequence containing this element resulted in the loss of approximately 50% of normal glutamate dehydrogenase expression. Gel mobility shift analysis indicated that a nuclear protein from Neurospora binds in a specific manner to sequences within the 90 bp fragment. We have now used a combination of ion-exchange and affinity chromatography to purify this nuclear protein, which we call Am Alpha Binding protein (AAB). The activity was monitored by gel shift analysis. The protein was purified more than 14,000-fold with a yield of approximately 7%. The purified protein appears as a heteromer on denaturing polyacrylamide gel electrophoresis, with only two strong bands visible in silver-stained preparations. One band has an apparent molecular mass of 40 kDa, the other appears as a doublet with an apparent molecular mass of 30 kDa. DNAse I protection analysis indicated a protected region consisting of 30 bp, which contains a CCAAT pentanucleotide motif. Mutagenesis of the CCAAT motif abolished the binding of AAB to the DNA fragment.

13C-labeled oligodeoxyribonucleotides: a solution study of a CCAAT-containing sequence at the nuclear factor I recognition site of human adenovirus

The solution behavior of the single-stranded CCAAT-containing octamer 1, d(AGCCAATA), that comprises part of the nuclear factor I (NF-I) recognition site at the origin of replication of human adenovirus has been studied by nmr spectroscopy at 500 and 600 MHz. Proton resonance assignments for 1 were aided by selective 13C enrichment at C1' of A1 or A5. High-resolution 13C-1H heteronuclear multiple-bond coherence spectra of the 13C-labeled oligomers permitted the selective detection of furanosyl ring protons within each labeled residue due to short- and long-range 13C-1H couplings to the enriched C1'. The resulting assignments provided firm starting points in the interpretation of double quantum filtered correlated spectra, yielding information supplemented by total correlated spectroscopy (TOCSY) and rotating frame nuclear Overhauser effect spectroscopic data to completely assign the 1H-nmr spectrum of 1 and extract 3JHH values for furanose conformational analysis. Several 13C-1H spin-coupling constants within the 13C-enriched A1 or A5 residues were measured from cross-peak shifts in TOCSY spectra, and their signs determined by inspection of the relative orientations of these shifts. 1H-1H and 13C-1H spin-couplings both indicate a preference (> 75%) for south (C2'-endo) conformations by the furanosyl rings of 1.

In vitro replication of bacteriophage PRD1 DNA. Characterization of the protein-primed initiation site

Bacteriophage PRD1 replicates its DNA by means of a protein-primed replication mechanism. Using single-stranded oligonucleotide templates carrying the sequence corresponding to the 25 first bases of the 3' end of PRD1 DNA, and Mg2+ as the activating metal ion of the phage DNA polymerase, we show that the fourth base from the 3' end of the template directs, by base complementarity, the dNMP to be linked to the phage terminal protein (TP) in the initiation reaction. This result suggests that phage PRD1 maintains its 3' end DNA sequences via a sliding-back mechanism. The single-stranded DNA templates could not be replicated by the PRD1 DNA polymerase, much in contrast to the natural TP-DNA. Nevertheless, the analysis of the transition products obtained with TP-DNA and origin-containing oligonucleotides suggests that sliding-back occurs stepwise, the fourth base being the directing position during the entire process.

Initiation of phi 29 DNA replication occurs at the second 3' nucleotide of the linear template: a sliding-back mechanism for protein-primed DNA replication

Bacteriophage phi 29 DNA replication is initiated when a molecule of dAMP is covalently linked to a free molecule of the terminal protein, in a reaction catalyzed by the viral DNA polymerase. We demonstrate that single-stranded DNA molecules are active templates for the protein-primed initiation reaction and can be replicated by phi 29 DNA polymerase. Using synthetic oligonucleotides, we carried out a mutational analysis of the phi 29 DNA right end to evaluate the effect of nucleotide changes at the replication origin and to determine the precise initiation site. The results indicate that (i) there are no strict sequence requirements for protein-primed initiation on single-stranded DNA; (ii) initiation of replication occurs opposite the second nucleotide at the 3' end of the template; (iii) a terminal repetition of at least two nucleotides is required to efficiently elongate the initiation complex; and (iv) all the nucleotides of the template, including the 3' terminal one, are replicated. A sliding-back model is proposed in which a special transition step from initiation to elongation can account for these results. The possible implication of this mechanism for the fidelity of the initiation reaction is discussed. Since all the terminal protein-containing genomes have some sequence reiteration at the DNA ends, this proposed sliding-back model could be extrapolable to other systems that use proteins as primers.

Mutations in two cysteine-histidine-rich clusters in adenovirus type 2 DNA polymerase affect DNA binding

Several point and linker insertion mutations in two Cys-His-rich regions of adenovirus (Ad) DNA polymerase (Pol) gene have been expressed in recombinant vaccinia virus. The resulting mutant enzymes were analyzed in vitro for their effects on DNA synthesis activity, on Ad-specific initiation assays, on gel shifts of Ad origin sequences, and on interactions with adenovirus preterminal protein (pTP) and nuclear factor I (NFI). In general, mutants in downstream Cys-His sequences had a pronounced effect in these assays. Mutants in the upstream Cys-His region had a moderate effect on DNA synthesis and elongation but failed to make dCMP-pTP initiation complexes and failed to make specific shifted complexes in a gel retardation assay. These mutants could still bind to pTP and NFI in a coimmunoprecipitation experiment, suggesting that this upstream Cys-His region of Ad Pol is involved either in specific Ad DNA origin binding or in nonspecific DNA binding. Changing residues within Cys doublets in the downstream Cys-His region had pronounced effects on many Ad Pol functions such as DNA synthesis, DNA binding, and in vitro initiation; however, these mutants showed little reduction in binding to pTP and NFI; mutants at other cysteines or histidines within this region of Ad Pol did not appear to have an effect on enzyme function. This observation suggests that the downstream Cys-His region of Ad Pol is important for DNA binding and might fold into a Zn finger motif.

Nuclear factor I is specifically targeted to discrete subnuclear sites in adenovirus type 2-infected cells

During the S phase of the eukaryotic cell cycle and in virus-infected cells, DNA replication takes place at discrete sites in the nucleus, although it is not clear how the proteins involved in the replicative process are directed to these sites. Nuclear factor I is a cellular, sequence-specific DNA-binding protein utilized by adenovirus type 2 to facilitate the assembly of a nucleoprotein complex at the viral origin of DNA replication. Immunofluorescence experiments reveal that in uninfected cells, nuclear factor I is distributed evenly throughout the nucleus. However, after a cell is infected with adenovirus type 2, the distribution of nuclear factor I is dramatically altered, being colocalized with the viral DNA-binding protein in a limited number of subnuclear sites which bromodeoxyuridine pulse-labeling experiments have identified as sites of viral DNA replication. Experiments with adenovirus type 4, which does not require nuclear factor I for viral DNA replication, indicate that although the adenovirus type 4 DNA-binding protein is localized to discrete nuclear sites, this does not result in the redistribution of nuclear factor I. Localization of nuclear factor I to discrete subnuclear sites is therefore likely to represent a specific targeting event that reflects the requirement for nuclear factor I in adenovirus type 2 DNA replication.

Analysis of multiple forms of nuclear factor I in human and murine cell lines

Nuclear factor I (NFI) is a group of related site-specific DNA-binding proteins that function in adenovirus DNA replication and cellular RNA metabolism. We have measured both the levels and forms of NFI that interact with a well-characterized 26-base-pair NFI-binding site. Five different NFI-DNA complexes were seen in HeLa nuclear extracts by using a gel mobility shift (GMS) assay. In addition, at least six forms of NFI were shown to cross-link directly to DNA by using a UV cross-linking assay. The distinct GMS complexes detected were composed of different subspecies of NFI polypeptides as assayed by UV cross-linking. Different murine cell lines possessed varying levels and forms of NFI binding activity, as judged by nitrocellulose filter binding and GMS assays. The growth state of NIH 3T3 cells affected both the types of NFI-DNA complexes seen in a GMS assay and the forms of the protein detected by UV cross-linking.

Analysis of multiple forms of nuclear factor I in human and murine cell lines

Nuclear factor I (NFI) is a group of related site-specific DNA-binding proteins that function in adenovirus DNA replication and cellular RNA metabolism. We have measured both the levels and forms of NFI that interact with a well-characterized 26-base-pair NFI-binding site. Five different NFI-DNA complexes were seen in HeLa nuclear extracts by using a gel mobility shift (GMS) assay. In addition, at least six forms of NFI were shown to cross-link directly to DNA by using a UV cross-linking assay. The distinct GMS complexes detected were composed of different subspecies of NFI polypeptides as assayed by UV cross-linking. Different murine cell lines possessed varying levels and forms of NFI binding activity, as judged by nitrocellulose filter binding and GMS assays. The growth state of NIH 3T3 cells affected both the types of NFI-DNA complexes seen in a GMS assay and the forms of the protein detected by UV cross-linking.

Sequence signals in eukaryotic upstream regions

Two DNA sequence elements are known to recur frequently upstream of eukaryotic polymerase II-transcribed genes. The TATAAA, at position -40, specifies the transcription initiation site. The GGCCAATCT is less frequent around -80. Sequence analysis of upstream regions reveals that the underlined yeast UAS2 consensus sequence, TGATTGGT, is also very frequent at -80 in higher polymerase II-transcribed animal sequences. The underlined CCAAT box and yeast UAS sequences are complementary. Structural analysis suggests some symmetry in their DNA structures. Upstream of the TATAAT-rich region there is an abundance of GC sequences. Analysis of nucleotide tracts indicates that these are preferentially flanked by their complementary nucleotides with a pyrimidine-purine junction, i.e., TTAN, CCGn, CnGG, TnAA. Here, I discuss DNA structural consideration in upstream regions along with protein readout of the major and minor groove information content. These sequence-structure aspects are put in the general context of protein (factors)-DNA (elements) recognition and regulation.

Adenoviruses with nonidentical terminal sequences are viable

Adenovirus genomes consist of linear DNA molecules containing inverted terminal repeat sequences (ITRs) of 100 to 200 base pairs. The importance of identical termini for viability of adenoviruses was investigated. The viral strains used in this study were wild-type adenovirus type 5 (Ad5) and a variant Ad2 strain with termini which were distinct from those of all other human adenoviruses sequenced to date. A hybrid virus (sub54), obtained by recombination between Ad2 and Ad5, derived the left 42 to 52% of its genome from Ad2 and the right 58 to 48% from Ad5. Southern blotting analysis with labeled oligodeoxynucleotides indicated that both Ad2 and Ad5 ITRs were present in sub54 viral DNA preparations, and successive plaque purifications of sub54 demonstrated that viruses with nonidentical terminal sequences were viable but were rapidly converted to viruses with identical ends. Cloning of the sub54 genome as a bacterial plasmid supported the observations made by analysis of sub54 virion DNA. A plasmid, pFG154, was isolated which contained the entire adenovirus genome with an Ad2 ITR at the left terminus covalently linked to an Ad5 ITR at the right terminus. Upon transfection of mammalian cells with pFG154, viral progeny were obtained which had all possible combinations of termini, thus confirming that molecules with nonidentical termini are viable. Pure populations of viruses with nonidentical termini could not be isolated, suggesting efficient repair of one end with the opposite terminus used as a template. A model for this process is proposed involving strand displacement replication and emphasizing the importance of panhandle formation (annealing of terminal sequences) as a replicative intermediate.

A GC-box motif upstream of the B19 parvovirus unique promoter is important for in vitro transcription

Nucleotides upstream of the B19 parvovirus P6 promoter affect in vitro transcription in HeLa cell nuclear extracts. Comparison of the relative transcriptional strengths of equimolar mixes of plasmids containing the intact upstream sequence and plasmids containing deletions within these nucleotides identified several regions that affect transcription in vitro. A fragment containing two of five GC-box motifs which correspond to high-affinity SP1-binding sites was shown, by using a gel shift assay, to bind a HeLa cell factor (or factors). DNase I, methylation interference, and methylation protection footprinting demonstrated that the HeLa cell factor(s) bound to one of the two GC-box motifs within this fragment. Mutation of this GC box abolished factor binding and significantly reduces in vitro transcription from the P6 promoter. These results suggest that the B19 parvovirus promoter includes a complex regulatory region containing multiple sequences which affect promoter strength and that the GC-box motif is a major controlling sequence for in vitro transcription.

Dual function of a nuclear factor I binding site in MMTV transcription regulation

Using linker-scanning mutagenesis we had previously identified four elements within the MMTV LTR which are necessary for transcriptional stimulation by glucocorticoid hormones. Two of them overlapped with regions to which the glucocorticoid receptor binds in vitro. The third element contained a NF-I binding site, and the fourth the TATA box. Here we show that mutations that abolish in vitro binding of NF-I had a negative effect also on the basal activity of the MMTV promoter of LTR-containing plasmids stably integrated in Ltk- fibroblasts. The analysis of double mutants altered in the NF-I plus either one of the receptor binding elements further demonstrated that the NF-I site functionally cooperated with the proximal (-120) element, which alone was extremely inefficient in stimulation. The stronger distal (-181/-172) element was independent of NF-I and showed functional cooperativity with the proximal hormone-binding element.

Sequence and structural requirements of a herpes simplex viral DNA replication origin

Herpes simplex virus (HSV) types 1 and 2 contain two classes of origins of DNA replication, oriS and oriL, which are closely related. A series of plasmids was constructed which contained specifically altered versions of the HSV type 2 oriS replication origin. Their ability to replicate in an in vivo replicon assay allowed a core origin of 75 base pairs (bp) to be defined. It included both arms of a 56-bp palindrome and from 13 to 20 bp of sequence leftward of the palindrome. The AT-rich sequence at the center of the palindrome was essential. Sequences on either side of the core origin enhanced replication. When additional copies of the -AT-dinucleotide were introduced progressively into the center of the palindrome, an oscillating effect on origin function was observed. These and other data implicate a linear rather than a cruciform conformation of the oriS palindrome in the initiation of HSV replication.

Sequence and structural requirements of a herpes simplex viral DNA replication origin

Herpes simplex virus (HSV) types 1 and 2 contain two classes of origins of DNA replication, oriS and oriL, which are closely related. A series of plasmids was constructed which contained specifically altered versions of the HSV type 2 oriS replication origin. Their ability to replicate in an in vivo replicon assay allowed a core origin of 75 base pairs (bp) to be defined. It included both arms of a 56-bp palindrome and from 13 to 20 bp of sequence leftward of the palindrome. The AT-rich sequence at the center of the palindrome was essential. Sequences on either side of the core origin enhanced replication. When additional copies of the -AT-dinucleotide were introduced progressively into the center of the palindrome, an oscillating effect on origin function was observed. These and other data implicate a linear rather than a cruciform conformation of the oriS palindrome in the initiation of HSV replication.

Interaction between the octamer-binding protein nuclear factor III and the adenovirus origin of DNA replication

Nuclear factor III (NFIII) is a HeLa sequence-specific DNA-binding protein that stimulates initiation of adenovirus DNA replication in vitro and may be involved in regulation of transcription of several cellular and viral genes. We have studied the interaction between NFIII and the binding site in the adenovirus type 2 (Ad2) origin in detail by methidiumpropyl-EDTA.iron(II) and hydroxyl radical footprinting and by alkylation interference experiments. Our results indicate that (i) the core of the recognition sequence is 5'-TATGATAAT-3'; (ii) both major and minor groove base contacts are detected, and all base pairs in the core are involved in binding; (iii) many backbone contacts are observed divided into a large domain coinciding with the core and a small domain; (iv) contact points are not confined to one side of the DNA helix in contrast to the nuclear factor I (NFI)-binding site; (v) the binding site overlaps the NFI-binding site for at least one nucleotide. A number of Ad2 mutants as well as related binding sites in the origins of other adenovirus serotypes were systematically compared for binding with NFIII. The results are in good agreement with the contact point studies and show that at least one AT base pair is commonly required by NFI and NFIII for optimal binding. The strongest binding site, which contains the octamer/decanucleotide motif (ATGCAAAT[NA]), was found in the Ad4 origin, which lacks an NFI-binding site. Stimulation of in vitro DNA replication of Ad2, Ad4, and Ad12 by NFIII showed that the maximal level of stimulation is dependent on the affinity of NFIII for the origin.

Structural and functional analysis of mitochondrial plasmids in Claviceps purpurea

Several strains of Claviceps purpurea, a phytopathogenic Ascomycete, contain mitochondrial (mt) plasmids in high molar excess relative to mtDNA. Comparative analysis of plasmids of four strains of different geographic origin revealed that all the plasmids are structurally related (size; linearity; restriction map; probably 5'-linked terminal protein; terminal inverted repeats, TIRs); two of them are even identical, indicating a possible mobility of these genetic entities. In strain K it was shown that plasmid titres are comparably high in axenic cultures and in parasitic structures (sclerotia). Detailed analysis of plasmid pClK1 proved the existence of a perfect TIR of 327 bp; the plasmid's structure and details of its nucleotide sequence indicate a replication modus comparable to that of adenoviruses. pClK1 is almost completely transcribed resulting in two major transcripts of 3.5 and 3.15 kb, respectively. In plasmid-free strains (cured by ethidium bromide treatment) these mRNAs are not detectable; nevertheless they show no significant difference in phenotype. As judged from their structural properties they could be derived from viral ancestors. In this context the plasmids' close relationship to mt plasmids of higher plants may be of special interest.

A family of human CCAAT-box-binding proteins active in transcription and DNA replication: cloning and expression of multiple cDNAs

The CTF/NF-I group of cellular DNA binding proteins recognizes the sequence GCCAAT and is implicated in eukaryotic transcription as well as DNA replication. Molecular analysis of human CTF/NF-I complementary DNA clones reveals multiple messenger RNA species containing alternative coding regions, apparently as a result of differential splicing. Expression and functional analysis establish that individual gene products can bind to GCCAAT recognition sites and serve both as promoter-selective transcriptional activators and as initiation factors for DNA replication.

Stimulation of transcription in vitro by binding sites for nuclear factor I

Nuclear factor I (NFI) is a site-specific DNA binding protein required for the replication of adenovirus DNA in vitro and in vivo. We have examined the effect of natural and synthetic binding sites for NFI (FIB sites) on RNA synthesis in HeLa whole cell extracts. The natural binding site used is the 26bp FIB-2 site previously isolated from the human genome. When present upstream of the TATA box of the adenovirus major late promoter, the FIB-2 site stimulates RNA synthesis 3 to 5-fold. This stimulation occurs with either orientation of the FIB-2 site. A point mutation in FIB-2 that decreases NFI binding at least 100-fold reduces, but does not completely abolish, the stimulation of transcription. A number of synthetic binding sites for NFI were tested for the ability to increase RNA synthesis. The strongest binding sites stimulated transcription the most, while the weakest sites had the least effect. These studies strongly suggest a role for NFI and cellular FIB sites in the control of RNA synthesis.

Replication of adenovirus and SV40 chromosomes in vitro

As an approach to studying the mechanisms involved in the replication of eukaryotic chromosomes, we have developed and characterized cell-free replication systems for the animal viruses, adenovirus and SV40. In this report we summarize recent work on the proteins required for the initiation of DNA synthesis in these two systems. The adenovirus origin of DNA replication was shown to consist of three functionally distinct sequence domains. Cellular proteins that specifically recognize each of these domains were purified and characterized. Initiation of adenovirus DNA replication was reconstituted from two virus-encoded and three cell-encoded factors. The SV40 origin of replication consists of a 65 base pair DNA segment that contains a high affinity binding site for the viral initiation protein T antigen. Evidence is presented that the first step in initiation of SV40 DNA replication involves the specific binding of T antigen to the origin, followed by the local unwinding of the two strands of the template. The unwinding reaction is specific for DNA templates containing the SV40 origin and requires ATP hydrolysis. In addition to T antigen, efficient unwinding requires a cellular factor(s) that can be replaced by the single-stranded DNA binding protein of Escherichia coli. These results indicate that the recently discovered helicase activity of T antigen plays a central role in initiation of viral DNA synthesis.

Incorporation of 5-bromodeoxycytidine in the adenovirus 2 replication origin interferes with nuclear factor 1 binding

We have studied the binding of nuclear factor 1 (NFI), a human sequence-specific DNA-binding protein, to a DNA fragment substituted in vitro with 5-bromodeoxycytidine (5-BrdC). Even at low substitution grades binding of NFI to its recognition sequence was considerably lower than with the unsubstituted control fragment. We developed a procedure to cleave substituted DNA specifically at a BrdC residue and searched for contacts between NFI and 5-BrdC residues by an interference assay. Surprisingly, no specific contacts were found in or near the recognition sequence. It appeared instead that interference was inversely related to the distance of a 5-BrdC residue from the NFI binding site. Models to explain these results, including a possible sliding mechanism, are discussed.

Site-specific DNA binding of nuclear factor I: effect of the spacer region

Nuclear factor I (NFI) is a site-specific DNA binding protein required for the replication of adenovirus type 2 DNA in vitro and in vivo. To study sequence requirements for the interaction of NFI with DNA, we have measured the binding of the protein to a variety of synthetic sites. Binding sites for NFI (FIB sites) were previously shown to contain a consensus sequence composed of 2 motifs, TGG (Motif 1), and GCCAA (Motif 2), separated by a 6 or 7bp spacer region. To assess conserved sequences in the spacer region and flanking sequences which affect NFI binding, we have isolated clones from oligonucleotide libraries that contain the two motifs flanked by 3 degenerate nucleotides and separated by degenerate spacer regions of 6 or 7 nucleotides. With a 6bp spacer region, a strong bias exists for a C or A residue in the first position of the spacer. Sites with a 7bp spacer region contain a G and C or A residue at the first and second positions, respectively, of the spacer, but also possess conserved residues at other positions of the site.

Multiple tandemly repeated binding sites for cellular nuclear factor 1 that surround the major immediate-early promoters of simian and human cytomegalovirus

We show that the large DNA genomes of human and simian cytomegaloviruses (HCMV and SCMV, respectively) each contain multiple binding sites for purified cellular nuclear factor 1 (NF1) protein. Examination of the major immediate-early (IE) gene region in the HindIII H fragment of SCMV (Colburn) by filter binding assays showed that it competed 45-fold better than the single adenovirus type 2 binding site for NF1 protein and that it contained at least two distinct binding loci. Direct DNase I footprinting analyses of the 5' upstream locus detected at least 20 adjacent NF1-binding sites located between positions -600 and -1300 relative to the IE94 mRNA start site. DNA sequence analysis of the region revealed a conserved consensus NF1 recognition element (T)TGG(C/A)N5GCCAA embedded within each of 23 highly diverged 30-base-pair tandem repeats, together with a second downstream cluster of five consensus NF1-binding sites between positions +470 and +570 in the large first intron. Two separate NF1-binding loci were also found in the equivalent IE68 gene of HCMV(Towne) DNA, but in this case the DNA sequence and competition filter binding experiments indicated a maximum of only four to five consensus binding sites encompassing the promoter-enhancer region. In transient expression assays, neither the isolated upstream IE94 tandem repeats nor a synthetic single-copy consensus NF1-binding site acted as transcriptional cis activators or enhancers when placed adjacent to the simian virus 40 minimal early region promoter. We conclude that the large and complex 5' upstream promoter-regulatory region for the SCMV IE94 gene comprises two distinct domains. The previously described four sets of 13- to 18-base-pair interspersed repeat elements between -55 and -580 provide most of the high basal transcriptional strength, whereas the arrangement of further upstream tandemly repeated NF1-binding sites may contribute significantly to the expanded biological host range for expression of SCMV IE94 compared with HCMV IE68.

Sequence-specific interactions between cellular DNA-binding proteins and the adenovirus origin of DNA replication

The adenovirus origin of DNA replication contains three functionally distinct sequence domains (A, B, and C) that are essential for initiation of DNA synthesis. Previous studies have shown that domain B contains the recognition site for nuclear factor I (NF-I), a cellular protein that is required for optimal initiation. In the studies reported here, we used highly purified NF-I, prepared by DNA recognition site affinity chromatography (P. J. Rosenfeld and T. J. Kelly, Jr., J. Biol. Chem. 261:1398-1408, 1986), to investigate the cellular protein requirements for initiation of viral DNA replication. Our data demonstrate that while NF-I is essential for efficient initiation in vitro, other cellular factors are required as well. A fraction derived from HeLa cell nuclear extract (BR-FT fraction) was shown to contain all the additional cellular proteins required for the complete reconstitution of the initiation reaction. Analysis of this complementing fraction by a gel electrophoresis DNA-binding assay revealed the presence of two site-specific DNA-binding proteins, ORP-A and ORP-C, that recognized sequences in domains A and C, respectively, of the viral origin. Both proteins were purified by DNA recognition site affinity chromatography, and the boundaries of their binding sites were defined by DNase I footprint analysis. Additional characterization of the recognition sequences of ORP-A, NF-I, and ORP-C was accomplished by determining the affinity of the proteins for viral origins containing deletion and base substitution mutations. ORP-C recognized a sequence between nucleotides 41 and 51 of the adenovirus genome, and analysis of mutant origins indicated that efficient initiation of replication is dependent on the presence of a high-affinity ORP-C-binding site. The ORP-A recognition site was localized to the first 12 base pairs of the viral genome within the minimal origin of replication. These data provide evidence that the initiation of adenovirus DNA replication involves multiple protein-DNA interactions at the origin.

Adenovirus origin of DNA replication: sequence requirements for replication in vitro

The initiation of adenovirus DNA takes place at the termini of the viral genome and requires the presence of specific nucleotide sequence elements. To define the sequence organization of the viral origin, we tested a large number of deletion, insertion, and base substitution mutants for their ability to support initiation and replication in vitro. The data demonstrate that the origin consists of at least three functionally distinct domains, A, B, and C. Domain A (nucleotides 1 to 18) contains the minimal sequence sufficient for origin function. Domains B (nucleotides 19 to 40) and C (nucleotides 41 to 51) contain accessory sequences that significantly increase the activity of the minimal origin. The presence of domain B increases the efficiency of initiation by more than 10-fold in vitro, and the presence of domains B and C increases the efficiency of initiation by more than 30-fold. Mutations that alter the distance between the minimal origin and the accessory domains by one or two base pairs dramatically decrease initiation efficiency. This critical spacing requirement suggests that there are specific interactions between the factors that recognize the two regions.

Adenovirus origin of DNA replication: sequence requirements for replication in vitro

The initiation of adenovirus DNA takes place at the termini of the viral genome and requires the presence of specific nucleotide sequence elements. To define the sequence organization of the viral origin, we tested a large number of deletion, insertion, and base substitution mutants for their ability to support initiation and replication in vitro. The data demonstrate that the origin consists of at least three functionally distinct domains, A, B, and C. Domain A (nucleotides 1 to 18) contains the minimal sequence sufficient for origin function. Domains B (nucleotides 19 to 40) and C (nucleotides 41 to 51) contain accessory sequences that significantly increase the activity of the minimal origin. The presence of domain B increases the efficiency of initiation by more than 10-fold in vitro, and the presence of domains B and C increases the efficiency of initiation by more than 30-fold. Mutations that alter the distance between the minimal origin and the accessory domains by one or two base pairs dramatically decrease initiation efficiency. This critical spacing requirement suggests that there are specific interactions between the factors that recognize the two regions.

Sequence-specific interactions between cellular DNA-binding proteins and the adenovirus origin of DNA replication

The adenovirus origin of DNA replication contains three functionally distinct sequence domains (A, B, and C) that are essential for initiation of DNA synthesis. Previous studies have shown that domain B contains the recognition site for nuclear factor I (NF-I), a cellular protein that is required for optimal initiation. In the studies reported here, we used highly purified NF-I, prepared by DNA recognition site affinity chromatography (P. J. Rosenfeld and T. J. Kelly, Jr., J. Biol. Chem. 261:1398-1408, 1986), to investigate the cellular protein requirements for initiation of viral DNA replication. Our data demonstrate that while NF-I is essential for efficient initiation in vitro, other cellular factors are required as well. A fraction derived from HeLa cell nuclear extract (BR-FT fraction) was shown to contain all the additional cellular proteins required for the complete reconstitution of the initiation reaction. Analysis of this complementing fraction by a gel electrophoresis DNA-binding assay revealed the presence of two site-specific DNA-binding proteins, ORP-A and ORP-C, that recognized sequences in domains A and C, respectively, of the viral origin. Both proteins were purified by DNA recognition site affinity chromatography, and the boundaries of their binding sites were defined by DNase I footprint analysis. Additional characterization of the recognition sequences of ORP-A, NF-I, and ORP-C was accomplished by determining the affinity of the proteins for viral origins containing deletion and base substitution mutations. ORP-C recognized a sequence between nucleotides 41 and 51 of the adenovirus genome, and analysis of mutant origins indicated that efficient initiation of replication is dependent on the presence of a high-affinity ORP-C-binding site. The ORP-A recognition site was localized to the first 12 base pairs of the viral genome within the minimal origin of replication. These data provide evidence that the initiation of adenovirus DNA replication involves multiple protein-DNA interactions at the origin.

Purification of a cellular, double-stranded DNA-binding protein required for initiation of adenovirus DNA replication by using a rapid filter-binding assay

A rapid and quantitative nitrocellulose filter-binding assay is described for the detection of nuclear factor I, a HeLa cell sequence-specific DNA-binding protein required for the initiation of adenovirus DNA replication. In this assay, the abundant nonspecific DNA-binding activity present in unfractionated HeLa nuclear extracts was greatly reduced by preincubation of these extracts with a homopolymeric competitor DNA. Subsequently, specific DNA-binding activity was detected as the preferential retention of a labeled 48-base-pair DNA fragment containing a functional nuclear factor I binding site compared with a control DNA fragment to which nuclear factor I did not bind specifically. This specific DNA-binding activity was shown to be both quantitative and time dependent. Furthermore, the conditions of this assay allowed footprinting of nuclear factor I in unfractionated HeLa nuclear extracts and quantitative detection of the protein during purification. Using unfrozen HeLa cells and reagents known to limit endogenous proteolysis, nuclear factor I was purified to near homogeneity from HeLa nuclear extracts by a combination of standard chromatography and specific DNA affinity chromatography. Over a 400-fold purification of nuclear factor I, on the basis of the specific activity of both sequence-specific DNA binding and complementation of adenovirus DNA replication in vitro, was affected by this purification. The most highly purified fraction was greatly enriched for a polypeptide of 160 kilodaltons on silver-stained sodium dodecyl sulfate-polyacrylamide gels. Furthermore, this protein cosedimented with specific DNA-binding activity on glycerol gradients. That this fraction indeed contained nuclear factor I was demonstrated by both DNase I footprinting and its function in the initiation of adenovirus DNA replication. Finally, the stoichiometry of specific DNA binding by nuclear factor I is shown to be most consistent with 2 mol of the 160-kilodalton polypeptide binding per mol of nuclear factor I-binding site.

Alu-family repeat binding protein from HeLa cells which interacts with regulatory region of SV40 virus genome

Using a gel retardation assay the protein which binds selectively to the Alu-family repeat (AFR) has been identified and partially purified from HeLa cell nuclear extract. The protein (AFR-binding protein, ABP) forms multiple discrete complexes with AFR even in the presence of 200 to 2000-fold excess of non-specific (E. coli) DNA. The most stable complex has a relative mobility in 4% polyacrylamide gel (as compared to the free Alu-fragment) of 0.54. Heterogeneity of protein-DNA bands seen in the polyacrylamide gel suggests that ABP is able to form multimeric complexes with AFR. Competition experiments show that ABP does not interact with the RNA polymerase III promoter and with the TGGCA-sequence, but a high affinity binding site for ABP was found within a 660 bp restriction fragment containing the SV40 virus promoter and replication origin.

Template requirements for in vivo replication of adenovirus DNA

The adenovirus (Ad) DNA origin of replication was defined through an analysis of the DNA sequences necessary for the replication of plasmid DNAs with purified viral and cellular proteins. Results from several laboratories have shown that the origin consists of two functionally distinct domains: a 10-base-pair sequence present in the inverted terminal repetition (ITR) of all human serotypes and an adjacent sequence constituting the binding site for a cellular protein, nuclear factor I. To determine whether the same nucleotide sequences are necessary for origin function in vivo, we developed an assay for the replication of plasmid DNAs transfected into Ad5-infected cells. The assay is similar to that described by Hay et al. (J. Mol. Biol. 175:493-510, 1984). With this assay, plasmid DNA replication is dependent upon prior infection of cells with virus and only occurs with linear DNA molecules containing viral terminal sequences at each end. Replicated DNA is resistant to digestion with lambda-exonuclease, suggesting that a protein is covalently bound at both termini. A plasmid containing only the first 67 base pairs of the Ad2 ITR replicates as well as plasmids containing the entire ITR. Deletions or point mutations which reduce the binding of nuclear factor I to DNA in vitro reduce the efficiency of plasmid replication in vivo. A point mutation within the 10-base-pair conserved sequence has a similar effect upon replication. These results suggest that the two sequence domains of the Ad origin identified by in vitro studies are in fact important for viral DNA replication in infected cells. In addition, we found that two separate point mutations which lie outside these two sequence domains, and which have little or no effect upon DNA replication in vitro, also reduce the apparent efficiency of plasmid replication in vivo. Thus, there may be elements of the Ad DNA origin of replication which have not yet been identified by in vitro studies.

Analysis of nuclear factor I binding to DNA using degenerate oligonucleotides

Nuclear factor I (NFI) binds tightly to DNA containing the consensus sequence TGG(N)6-7GCCAA. To study the role of the spacing between the TGG and GCCAA motifs, oligonucleotides homologous to the NFI binding site FIB-2 were synthesized and used for binding assays in vitro. The wild-type site (FIB-2.6) has a 6bp spacer region and binds tightly to NFI. When the size of this spacer was altered by +/- 1 or 2bp the binding to NFI was abolished. To further assess the role of the spacer and bases flanking the motifs, two oligonucleotide libraries were synthesized. Each member of these libraries had intact TGG and GCCAA motifs, but the sequence of the spacer and the 3bp next to each motif was degenerate. The library with a 6bp spacer bound to NFI to 40-50% the level of FIB-2.6. The library with a 7bp spacer bound to NFI to only 4% the level of FIB-2.6 and some of this binding was weaker than that of FIB-2.6 DNA. This novel use of degenerate DNA libraries has shown that: 1) the structural requirements for FIB sites with a 7bp spacer are more stringent than for sites with a 6bp spacer and 2) a limited number of DNA structural features can prevent the binding of NFI to sites with intact motifs and a 6bp spacer region.

MDBK nuclear factor-binding site of various serotypes of adenovirus DNA

A fraction with the ability to bind the terminal fragment of equine adenovirus (EAd) DNA was prepared from MDBK cell nuclei. The fraction (MDBK nuclear factor) bound to the terminal fragment of all human and animal adenovirus DNAs examined except avian adenovirus EDS-76. However, the terminal fragments of two animal adenoviruses, EAd and bovine adenovirus type 3 (BAd3), showed higher affinity for the nuclear factor than the others. The MDBK nuclear factor-binding site determined by footprinting analysis was the sequence located between nucleotides 22 and 46 in EAd, between 36 and 53 in canine adenovirus type 2, and between 20 and 46 in BAd3, counting from the terminus. The respective binding site contained a sequence resembling the consensus sequence. The binding site of Ad4 DNA was not within the inverted terminal repetition, but was located at least 550 base pairs apart from the terminus.

Nuclear factor III, a novel sequence-specific DNA-binding protein from HeLa cells stimulating adenovirus DNA replication

Dissection and reconstitution of the adenovirus DNA replication machinery has led to the discovery of two HeLa nuclear proteins which are required in conjunction with three viral proteins. One of these, nuclear factor I (NF-I), recognizes an internal region of the origin between nucleotides 25 and 40 and by binding to one side of the helix stimulates the initiation reaction up to 30-fold. NFI-binding sites have been observed upstream of several cellular genes, such as chicken lysozyme, human IgM and human c-myc, and coincide in most cases with DNase I hypersensitive regions. Here we report the identification of a novel DNA-binding protein from HeLa nuclei, designated NF-III, that recognizes a sequence in the adenovirus origin very close to the NFI-binding site, between nucleotides 36 and 54. This sequence includes the partially conserved nucleotides TATGATAATGAG. NF-III stimulates DNA replication four- to sixfold by increasing the initiation efficiency. Potential cellular binding sites include promoter elements of the histone H2B gene, the human interferon beta gene, the human and mouse immunoglobulin VK and VH genes and the mammal/chicken/Xenopus laevis U1 and U2 small nuclear RNA genes. Furthermore, a subset of the herpes simplex virus immediate early promoter specific TAATGARAT elements is homologous with the adenovirus 2 (Ad-2) NFIII-binding site.

Template requirements for in vivo replication of adenovirus DNA

The adenovirus (Ad) DNA origin of replication was defined through an analysis of the DNA sequences necessary for the replication of plasmid DNAs with purified viral and cellular proteins. Results from several laboratories have shown that the origin consists of two functionally distinct domains: a 10-base-pair sequence present in the inverted terminal repetition (ITR) of all human serotypes and an adjacent sequence constituting the binding site for a cellular protein, nuclear factor I. To determine whether the same nucleotide sequences are necessary for origin function in vivo, we developed an assay for the replication of plasmid DNAs transfected into Ad5-infected cells. The assay is similar to that described by Hay et al. (J. Mol. Biol. 175:493-510, 1984). With this assay, plasmid DNA replication is dependent upon prior infection of cells with virus and only occurs with linear DNA molecules containing viral terminal sequences at each end. Replicated DNA is resistant to digestion with lambda-exonuclease, suggesting that a protein is covalently bound at both termini. A plasmid containing only the first 67 base pairs of the Ad2 ITR replicates as well as plasmids containing the entire ITR. Deletions or point mutations which reduce the binding of nuclear factor I to DNA in vitro reduce the efficiency of plasmid replication in vivo. A point mutation within the 10-base-pair conserved sequence has a similar effect upon replication. These results suggest that the two sequence domains of the Ad origin identified by in vitro studies are in fact important for viral DNA replication in infected cells. In addition, we found that two separate point mutations which lie outside these two sequence domains, and which have little or no effect upon DNA replication in vitro, also reduce the apparent efficiency of plasmid replication in vivo. Thus, there may be elements of the Ad DNA origin of replication which have not yet been identified by in vitro studies.

Purification of a cellular, double-stranded DNA-binding protein required for initiation of adenovirus DNA replication by using a rapid filter-binding assay

A rapid and quantitative nitrocellulose filter-binding assay is described for the detection of nuclear factor I, a HeLa cell sequence-specific DNA-binding protein required for the initiation of adenovirus DNA replication. In this assay, the abundant nonspecific DNA-binding activity present in unfractionated HeLa nuclear extracts was greatly reduced by preincubation of these extracts with a homopolymeric competitor DNA. Subsequently, specific DNA-binding activity was detected as the preferential retention of a labeled 48-base-pair DNA fragment containing a functional nuclear factor I binding site compared with a control DNA fragment to which nuclear factor I did not bind specifically. This specific DNA-binding activity was shown to be both quantitative and time dependent. Furthermore, the conditions of this assay allowed footprinting of nuclear factor I in unfractionated HeLa nuclear extracts and quantitative detection of the protein during purification. Using unfrozen HeLa cells and reagents known to limit endogenous proteolysis, nuclear factor I was purified to near homogeneity from HeLa nuclear extracts by a combination of standard chromatography and specific DNA affinity chromatography. Over a 400-fold purification of nuclear factor I, on the basis of the specific activity of both sequence-specific DNA binding and complementation of adenovirus DNA replication in vitro, was affected by this purification. The most highly purified fraction was greatly enriched for a polypeptide of 160 kilodaltons on silver-stained sodium dodecyl sulfate-polyacrylamide gels. Furthermore, this protein cosedimented with specific DNA-binding activity on glycerol gradients. That this fraction indeed contained nuclear factor I was demonstrated by both DNase I footprinting and its function in the initiation of adenovirus DNA replication. Finally, the stoichiometry of specific DNA binding by nuclear factor I is shown to be most consistent with 2 mol of the 160-kilodalton polypeptide binding per mol of nuclear factor I-binding site.

A sensitive and rapid gel retention assay for nuclear factor I and other DNA-binding proteins in crude nuclear extracts

The paper describes a rapid and sensitive assay for DNA binding proteins which interact with specific and defined binding sites. It exploits the observation that complexes of proteins and small synthetic DNA fragments (40 bp) containing the protein/DNA binding site can enter native polyacrylamide gels and remain stably associated during electrophoresis under non-denaturing conditions. The assay was applied to nuclear factor I, to its identification and purification from porcine liver, to an analysis of its binding site on adenovirus type 5 DNA and to an exploration of other potential binding sites for DNA binding proteins within the inverted terminal repetition of adenovirus DNA. The extreme sensitivity of the assay which surpasses that of conventional footprint assays by at least two orders of magnitude permitted the identification of nuclear factor I-like activities in Saccharomyces cerevisiae.

Activation of the major immediate early gene of human cytomegalovirus by cis-acting elements in the promoter-regulatory sequence and by virus-specific trans-acting components

Upstream of the major immediate early gene of human cytomegalovirus (Towne) is a strong promoter-regulatory region that promotes the synthesis of 1.95-kilobase mRNA (D. R. Thomsen, R. M. Stenberg, W. F. Goins, and M. F. Stinski, Proc. Natl. Acad. Sci. U.S.A. 81:659-663, 1984; M. F. Stinski, D. R. Thomsen, R. M. Stenberg, and L. C. Goldstein, J. Virol. 46:1-14, 1983). The wild-type promoter-regulatory region as well as deletions within this region were ligated upstream of the thymidine kinase, chloramphenicol acetyltransferase, or ovalbumin genes. These gene chimeras were constructed to investigate the role of the regulatory sequences in enhancing downstream expression. The regulatory region extends to approximately 465 nucleotides upstream of the cap site for the initiation of transcription. The extent and type of regulatory sequences upstream of the promoter influences the level of in vitro transcription as well as the amount of in vivo expression of the downstream gene. The regulatory elements for cis-activation appear to be repeated several times within the regulatory region. A direct correlation was established between the distribution of the 19 (5' CCCCAGTTGACGTCAATGGG 3')- and 18 (5' CACTAACGGGACTTTCCAA 3')-nucleotide repeats and the level of downstream expression. In contrast, the 16 (5' CTTGGCAGTACATCAA 3')-nucleotide repeat is not necessary for the enhancement of downstream expression. In a domain associated with the 19- or 18-nucleotide repeats are elements that can be activated in trans by a human cytomegalovirus-specified component but not a herpes simplex virus-specified component. Therefore, the regulatory sequences of the major immediate early gene of human cytomegalovirus have an important role in interacting with cellular and virus-specific factors of the transcription complex to enhance downstream expression of this critical viral gene.

Adenovirus sequences required for replication in vivo

We have studied the in vivo replication properties of plasmids carrying deletion mutations within cloned adenovirus terminal sequences. Deletion mapping located the adenovirus DNA replication origin entirely within the first 67 bp of the adenovirus inverted terminal repeat. This region could be further subdivided into two functional domains: a minimal replication origin and an adjacent auxillary region which boosted the efficiency of replication by more than 100-fold. The minimal origin occupies the first 18 to 21 bp and includes sequences conserved between all adenovirus serotypes. The adjacent auxillary region extends past nucleotide 36 but not past nucleotide 67 and contains the binding site for nuclear factor I.