The adenovirus DNA binding protein and adenovirus DNA polymerase interact to catalyze elongation of primed DNA templates

Viral and cellular interactions during adenovirus DNA replication

Adenoviruses represent ubiquitous and clinically significant human pathogens, gene-delivery vectors, and oncolytic agents. The study of adenovirus-infected cells has long been used as an excellent model to investigate fundamental aspects of both DNA virus infection and cellular biology. While many key details supporting a well-established model of adenovirus replication have been elucidated over a period spanning several decades, more recent findings suggest that we have only started to appreciate the complex interplay between viral genome replication and cellular processes. Here, we present a concise overview of adenovirus DNA replication, including the biochemical process of replication, the spatial organization of replication within the host cell nucleus, and insights into the complex plethora of virus-host interactions that influence viral genome replication. Finally, we identify emerging areas of research relating to the replication of adenovirus genomes.

Computational analysis of adenovirus serotype 5 (HAdV-C5) from an HAdV coinfection shows genome stability after 45 years of circulation

Adenovirus coinfections present opportunities for genome recombination. Computational analysis of an HAdV-C5 field strain genome, recovered from a patient with acute respiratory disease and coinfected with HAdV-B21, shows that there was no exchange of genomic material into HAdV-C5. Comparison of this genome to the sparsely amplified prototype demonstrates a high level of sequence conservation and stability of this genome across 45 years. Further, comparison to a version of the prototype that had been passaged in laboratory settings shows stability as well. HAdV genome stability and evolution are considerations for applications as vaccines and as vectors for gene delivery. In the annotation analysis, a single sequencing error in the HAdV-C5_ARM (Adenovirus Reference Material) genome is noted and may lead to erroneous annotation and biological interpretations.

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.

Adenovirus DNA replication: protein priming, jumping back and the role of the DNA binding protein DBP

The adenovirus (Ad) genome is a linear double-stranded (ds) molecule containing about 36 kilobase pairs. At each end of the genome an approximately 100 base pair (bp) inverted terminal repeat (ITR) is found, the exact length depending on the serotype. To the 5'-end of each ITR, a 55-kDa terminal protein (TP) is covalently coupled. The Ad DNA replication system was one of the first replication systems that could be reconstituted in vitro (Challberg and Kelly 1979). The system requires three virally encoded proteins: precursor TP (pTP), DNA polymerase (Pol) and the DNA binding protein (DBP). In addition, three stimulating human cellular proteins have been identified. These are the transcription factors NFI (Nagata et al. 1982) and Oct-1 (Pruijn et al. 1986) and the type I topoisomerase NFII (Nagata et al. 1983). Ad DNA replication uses a protein primer for replication initiation. The transition from initiation to elongation is marked by a jumping back mechanism (King and van der Vliet 1994), followed by elongation. In order to elongate DBP is required. In this review we discuss the roles of DBP during initiation and elongation and we relate biochemical data on the jumping back mechanism used by Ad Pol to the recently solved crystal structure of a Pol alpha-like replication complex (Franklin et al. 2001). We comment on the conditions and possible functions of jumping back and propose a model to describe the jumping back mechanism.

Adenovirus type 5 DNA binding protein stimulates binding of DNA polymerase to the replication origin

The adenovirus (Ad) DNA-binding protein (DBP) is essential for the elongation phase of Ad DNA replication by unwinding the template in an ATP-independent fashion, employing its capacity to form multimers. DBP also enhances the rate of initiation, with the highest levels obtained at low concentrations of Ad DNA polymerase (Pol). Here, we show that stimulation of initiation depends on the template conformation. Maximal stimulation, up to 15-fold, is observed on double-stranded or viral TP-containing origins. The stimulation is reduced on partially single-stranded origins and DBP does not enhance initiation any more once the origin is completely unwound. This suggests a role for DBP in origin unwinding that is comparable to its unwinding capacity during elongation. However, mutant DBP proteins defective in unwinding and elongation can still enhance initiation on ds templates. DBP also stimulates the binding of nuclear factor I (NFI) to the origin and lowers the K(m) for coupling of the first nucleotide to the precursor terminal protein by Pol. Mobility shift experiments reveal that DBP stimulates the binding of Pol on double-stranded origin and nonorigin DNA but not on single-stranded DNA. This effect is specific for DBP and is also seen with other DNA Pols. Our results suggest that, rather than by origin unwinding, DBP enhances initiation by modulating the origin conformation such that DNA Pol can bind more efficiently.

The formation of a flexible DNA-binding protein chain is required for efficient DNA unwinding and adenovirus DNA chain elongation

The adenovirus DNA-binding protein (DBP) binds cooperatively to single-stranded DNA (ssDNA) and stimulates both initiation and elongation of DNA replication. DBP consists of a globular core domain and a C-terminal arm that hooks onto a neighboring DBP molecule to form a stable protein chain with the DNA bound to the internal surface of the chain. This multimerization is the driving force for ATP-independent DNA unwinding by DBP during elongation. As shown by x-ray diffraction of different crystal forms of the C-terminal domain, the C-terminal arm can adopt different conformations, leading to flexibility in the protein chain. This flexibility is a function of the hinge region, the part of the protein joining the C-terminal arm to the protein core. To investigate the function of the flexibility, proline residues were introduced in the hinge region, and the proteins were purified to homogeneity after baculovirus expression. The mutant proteins were still able to bind ss- and double-stranded DNA with approximately the same affinity as wild type, and the binding to ssDNA was found to be cooperative. All mutant proteins were able to stimulate the initiation of DNA replication to near wild type levels. However, the proline mutants could not support elongation of DNA replication efficiently. Even the elongation up to 26 nucleotides was severely impaired. This defect was also seen when DNA unwinding was studied. Binding studies of DBP to homo-oligonucleotides showed an inability of the proline mutants to bind to poly(dA)(40), indicating an inability to adapt to specific DNA conformations. Our data suggest that the flexibility of the protein chain formed by DBP is important in binding and unwinding of DNA during adenovirus DNA replication. A model explaining the need for flexibility of the C-terminal arm is proposed.

ATP-independent DNA unwinding by the adenovirus single-stranded DNA binding protein requires a flexible DNA binding loop

The adenovirus DNA binding protein (DBP) binds cooperatively to single-stranded (ss) DNA and stimulates both initiation and elongation of DNA replication. DBP forms protein filaments via a C-terminal arm that hooks into a neighbouring molecule. This multimerization is the driving force for ATP-independent DNA unwinding by DBP during elongation. Another conserved part of DBP forms an unstructured flexible loop that is probably directly involved in contacting DNA. By making appropriate deletion mutants that do not distort the overall DBP structure, the influence of the C-terminal arm and the flexible loop on the kinetics of ssDNA binding and on DNA replication was studied. Employing surface plasmon resonance we show that both parts of the protein are required for high affinity binding. Deletion of the C-terminal arm leads to an extremely labile DBP-ssDNA complex indicating the importance of multimerization. The flexible loop is also required for optimal stability of the DBP-ssDNA complex, providing additional evidence that this region forms part of the ssDNA-binding surface of DBP. Both deletion mutants are still able to stimulate initiation of DNA replication but are defective in supporting elongation, which may be caused by the fact that both mutants have a reduced DNA unwinding activity. Surprisingly, mixtures containing both mutants do stimulate elongation. Mixing the purified mutant proteins leads to the formation of mixed filaments that have a higher affinity for ssDNA than homogeneous mutant filaments. These results provide evidence that the C-terminal arm and the flexible loop have distinct functions in unwinding during replication. We propose the following model for ATP-independent DNA unwinding by DBP. Multimerization via the C-terminal arm is required for the formation of a protein filament that saturates the displaced strand. A high affinity of a DBP monomer for ssDNA and subsequent local destabilization of the replication fork requires the flexible loop.

Role of the adenovirus DNA-binding protein in in vitro adeno-associated virus DNA replication

A basic question in adeno-associated virus (AAV) biology has been whether adenovirus (Ad) infection provided any function which directly promoted replication of AAV DNA. Previously in vitro assays for AAV DNA replication, using linear duplex AAV DNA as the template, uninfected or Ad-infected HeLa cell extracts, and exogenous AAV Rep protein, demonstrated that Ad infection provides a direct helper effect for AAV DNA replication. It was shown that the nature of this helper effect was to increase the processivity of AAV DNA replication. Left unanswered was the question of whether this effect was the result of cellular factors whose activity was enhanced by Ad infection or was the result of direct participation of Ad proteins in AAV DNA replication. In this report, we show that in the in vitro assay, enhancement of processivity occurs with the addition of either the Ad DNA-binding protein (Ad-DBP) or the human single-stranded DNA-binding protein (replication protein A [RPA]). Clearly Ad-DBP is present after Ad infection but not before, whereas the cellular level of RPA is not apparently affected by Ad infection. However, we have not measured possible modifications of RPA which might occur after Ad infection and affect AAV DNA replication. When the substrate for replication was an AAV genome inserted into a plasmid vector, RPA was not an effective substitute for Ad-DBP. Extracts supplemented with Ad-DBP preferentially replicated AAV sequences rather than adjacent vector sequences; in contrast, extracts supplemented with RPA preferentially replicated vector sequences.

Dissociation of the protein primer and DNA polymerase after initiation of adenovirus DNA replication

Initiation of adenovirus DNA replication occurs by a jumping back mechanism in which the precursor terminal priming protein (pTP) forms a pTP.trinucleotide complex (pTP.CAT) catalyzed by the viral DNA polymerase (pol). This covalent complex subsequently jumps back 3 bases to permit the start of chain elongation. Before initiation, pTP and pol form a tight heterodimer. We investigated the fate of this pTP.pol complex during the various steps in replication. Employing in vitro initiation and elongation on both natural viral templates and synthetic oligonucleotides followed by glycerol gradient separation of the reaction products, we established that pTP and pol are separated during elongation. Whereas pTP.C and pTP. CA were still bound to the polymerase, after the formation of pTP. CAT 60% of the pTP.pol complex had dissociated. Dissociation coincides with a change in sensitivity to inhibitors and in Km for dNTPs, suggesting a conformational change in the polymerase, both in the active site and in the pTP interaction domain. In agreement with this, the polymerase becomes a more efficient enzyme after release of the pTP primer. We also investigated whether the synthesis of a pTP initiation intermediate is confined to three nucleotides. Employing synthetic oligonucleotide templates with a sequence repeat of two nucleotides (GAGAGAGA ... instead of the natural GTAGTA ... ) we show that G5 rather than G3 is used to start, leading to a pTP. tetranucleotide (CTCT) intermediate that subsequently jumps back. This indicates flexibility in the use of the start site with a preference for the synthesis of three or four nucleotides during initiation rather than two.

Processive proofreading by the adenovirus DNA polymerase. Association with the priming protein reduces exonucleolytic degradation

By using a baculovirus expression system, the adenovirus (Ad) DNA polymerase was purified to homogeneity and shown to display a 3'-->5'exonuclease activity which is coupled to the polymerase activity. On a partial duplex structure the exonuclease activity had a marked preference for excision of a mismatched versus a matched 3'-terminus, which enables the Ad DNA polymerase to act as a proofreading enzyme. On single-stranded DNA the exonuclease action is distributive, but during replication removal of mismatched nucleotides and the switch to synthesis occurs without dissociation of the polymerase from the template. When the Ad DNA polymerase is bound to the precursor terminal protein, the rate of exonucleolysis was four times slower. Moreover, degradation could not proceed as far as with the free Ad polymerase, indicating also a qualitative difference. These results suggest a reduced proofreading capacity of the precursor terminal protein-polymerase complex, which might affect the initial stages of DNA replication.

Domain organization of the adenovirus preterminal protein

In adenovirus-infected cells, the virus-encoded preterminal protein and DNA polymerase form a heterodimer that is directly involved in initiation of DNA replication. Monoclonal antibodies were raised against preterminal protein, and epitopes recognized by the antibodies were identified by using synthetic peptides. Partial proteolysis of preterminal protein reveals that it has a tripartite structure, with the three domains being separated by two protease-sensitive areas, located at sites processed by adenovirus protease. These areas of protease sensitivity are probably surface-exposed loops, as they are the sites, along with the C-terminal region of preterminal protein, recognized by the monoclonal antibodies. Preterminal protein is protected from proteolytic cleavage when bound to adenovirus DNA polymerase, suggesting either multiple contact points between the proteins or a DNA polymerase-induced conformational change in preterminal protein. Two of the preterminal protein-specific antibodies induced dissociation of the preterminal protein-adenovirus DNA polymerase heterodimer and inhibited initiation of adenovirus DNA replication in vitro. Antibodies binding close to the primary processing sites of adenovirus protease inhibited DNA binding, consistent with UV cross-linking results which reveal that an N-terminal, protease-resistant domain of preterminal protein contacts DNA. Monoclonal antibodies recognizing epitopes within the C-terminal 60 amino acids of preterminal protein stimulate DNA binding, an effect mediated through a decrease in the dissociation rate constant. These results suggest that preterminal protein contains a large, noncontiguous surface required for interaction with DNA polymerase, an N-terminal DNA binding domain, and a C-terminal regulatory domain.

Pyridoxal 5'-phosphate inhibition of adenovirus DNA polymerase

Pyridoxal phosphate modification of adenovirus DNA polymerase results in loss of DNA polymerase activity, whereas the 3' --> 5' exonuclease activity is unaffected. Inhibition by pyridoxal phosphate is time-dependent, displays saturation kinetics, and is reversible in the presence of excess primary amine unless the pyridoxal phosphate-enzyme adduct is first reduced with NaBH4. Thus, inhibition is the consequence of Schiff base formation between the aldehyde moiety of pyridoxal phosphate and primary amino groups on the enzyme. In addition to inhibiting DNA polymerase activity, pyridoxal phosphate also inhibited the ability of the enzyme to initiate viral DNA replication, by transfer of dCMP onto the preterminal protein. Neither template-primer nor dNTP protect against pyridoxal phosphate inhibition, but the combination of template-primer and complementary substrate dNTP protected both initiation and DNA polymerase activities. Thus, it is likely that both the dCMP transfer activity required for initiation and DNA polymerase activity are carried out at the same site of the enzyme.

Predicted structure of the adenovirus DNA binding protein

The DNA sequence of a portion of the MAV1 SmaI-D fragment coding for the C-terminal 147 amino acids of the adenoviral DNA-binding protein (DBP) has been determined. A multiple sequence alignment was constructed of the MAV1 fragment and the DBPs of Ad.2, 4, 5, 7, 12, 40, and 41 to examine the degree of conservation of features that have been mapped on the Ad.2 DBP and to identify further conserved features. The less conserved N-terminal segment of the protein contains two nuclear localization signals and two acidic regions, the host range region, and all of the 11 phosphorylation sites. The highly conserved C-terminal segment contains a potential leucine zipper and zinc finger motifs. These sequence features were mapped onto a predicted secondary structure of the Ad.2 DBP.

Helix-destabilizing properties of the adenovirus DNA-binding protein

The adenovirus DNA-binding protein (DBP) is a multifunctional protein that is essential for viral DNA replication. DBP binds both single-stranded and double-stranded DNA as well as RNA in a sequence-independent manner. Previous studies showed that DBP does not promote melting of duplex poly(dA-dT) in contrast to prokaryotic single-strand-binding proteins. However, here we show that DBP can displace oligonucleotides annealed to single-stranded M13 DNA. Depending upon the DBP concentration, strands of at least 200 nucleotides can be unwound. Although unwinding of short (17-bp), fully duplex DNA is facilitated by DBP, unwinding of larger (28-bp) duplexes is only possible if single-stranded protruding ends are present. These protruding ends must be at least 4 nucleotides long for optimal unwinding, and both 5' and 3' single-stranded overhangs suffice. DBP-promoted strand displacement is sensitive to MgCl2 and NaCl and not dependent upon ATP. Our results suggest that DBP, through formation of a protein chain on the displaced strand, may destabilize duplex DNA ahead of the replication fork, thereby assisting in strand displacement during replication.

Replication of adenovirus DNA in vitro is ATP-independent

Using a reconstituted system for adenovirus DNA replication we tested the requirements for ATP and divalent cations. At the standard Mg2+ concentration ATP stimulated initiation 5 to 10-fold. However, this effect was caused by complexing Mg2+. At the optimal Mg2+ concentration ATP was not required for initiation or elongation. Besides Mg2+ also Mn2+, Ca2+ and Ba2+ were shown to support initiation whereas for elongation only Mg2+ was accepted. Since Mn2+ could efficiently be used for DNA chain elongation on synthetic templates we hypothesize that Mg2+ is essential for the transition of initiation to elongation.

Characterization of vaccinia virus DNA replication mutants with lesions in the D5 gene

The vaccinia virus D5 gene encodes a 90 kDa early protein that is essential for viral DNA replication. In this report we map and explore the phenotypes of the temperature sensitive mutants bearing lesions in this gene: ts17, ts24, ts69 (WR strain) and ts6389 (IHD strain). Viral DNA synthesis was virtually undetectable during non-permissive infections performed with ts17, and incorporation of 3H-thymidine ceased rapidly when cultures were shifted to the non-permissive temperature in the midst of replication. The D5 protein may therefore be involved in DNA synthesis at the replication fork. The lesions of the four mutants were localized within the D5 orf by marker rescue, and the single nucleotide changes responsible for the ts phenotype of the three WR mutants were identified. Unexpectedly, the three alleles with N-terminal mutations were impaired in marker rescue when homologous recombination with small (< 2 kb), intragenic DNA fragments at 39.5 degrees C was required. This deficiency was not due to degradation of transfected DNA under non-permissive conditions. Efficient marker rescue could be restored by incubation at the permissive temperature for a brief period after transfection, suggesting a requirement for functional D5 in genome/plasmid recombination. Marker rescue under non-permissive conditions could alternatively be restored by co-transfection of unlinked but contiguous DNA sequences.

Structural alterations of double-stranded DNA in complex with the adenovirus DNA-binding protein. Implications for its function in DNA replication

The Adenovirus DNA-binding protein (DBP) binds to single-stranded (ss) DNA as well as to double-stranded (ds) DNA and forms multimeric protein-DNA complexes with both. Gel retardation assays indicate rapid complex formation for both DNAs. DBP rapidly dissociates from dsDNA, indicating a dynamic equilibrium, whereas the ssDNA-DBP complex is much more stable. We investigated the complex between DBP and dsDNA in more detail. Electron microscopical analysis shows thick filament-like and beaded structures in which the length of the DNA is not significantly altered. Cryo-electron micrographs suggest the presence of interwound protein fibres around the DNA. Ligase-mediated cyclization, but not linear multimerization, of DBP-saturated DNA fragments exceeding the persistence length was severely inhibited. This suggests that DNA may be organized by DBP into a rigid structure. Under those conditions, DBP induces distinct changes in the circular dichroism spectrum of the DNA, indicative of structural DNA changes. No bending or twisting of the complex was observed. Hydroxyl radical footprinting showed that the breakdown pattern of DNA at saturating DBP concentrations is much more regular than the protein-free DNA. This suggests the removal of tertiary structures, which may be related to the effects of DBP on enhanced NFI binding and chain elongation during Adenovirus DNA replication. Using purified proteins in an in vitro replication system, we correlate the structural changes with the effects of DBP on enhancement of NFI-binding as well as on DNA replication.

A zinc-binding motif located between amino acids 273 and 286 in the adenovirus DNA-binding protein is necessary for ssDNA binding

The human adenovirus single-stranded (ss) DNA-binding protein (DBP) possesses a highly conserved carboxyl domain which contains a putative zinc-binding motif between amino acids (aa) 273 and 286. Using a zinc blotting technique DBP was shown to bind 65Zn at levels similar to other documented zinc metalloproteins. In competition experiments, DBP bound specifically to the zinc ion even in the presence of other divalent ions such as Ca+2, Mg+2, Cd+2, Co+2, and Mn+2. The zinc-binding ability of DBP was also confirmed by zinc affinity chromatography. Site-directed mutagenesis was utilized to construct a mutant which deleted the entire zinc region (pKZNdl 273-286) and a mutant which contained a Cys to Ser substitution at aa residue 284 (pKZNpt 284). The deletion mutant was unable to bind zinc, and the point mutant showed limited binding suggesting that aa 273-286 are responsible for the interaction of DBP with zinc. The DBP zinc mutants were also examined for their ability to bind to ssDNA. The deletion mutant was unable to bind ssDNA cellulose while the point mutant exhibited decreased affinity. Thus, the region between aa 273 and 286 which mediates zinc binding also appears fundamental for the ssDNA-binding function of DBP.

Complementation of adenovirus early region 1a and 2a mutants by Epstein-Barr virus immortalized lymphoblastoid cell lines

Human B-lymphocytes may be infected by both adenoviruses and the Epstein-Barr virus (EBV). Some of the immediate early and early proteins in the two viruses are similar in function even though their primary structures are different. As these viruses might infect the same B-cells in man, we asked if complementation could take place. The adenovirus mutant H5ts125 has a thermolabile DNA-binding protein and is defective in DNA replication at 39 degrees. Several EBV-transformed human lymphoblastoid cell lines and a tamarin cell line B95-8 were infected with H5ts125 and incubated at either the nonpermissive or the permissive temperatures. Adenoviral DNA replication and assembly of new virions were observed at both temperatures, suggesting complementation by the resident EBV gene products. The adenovirus E1a region is deleted in the mutant d1312. Complementation of this mutant was only obtained in the EBV producer B95-8 cells. Immortalization by EBV was apparently not sufficient for effective complementation. This supports an earlier observation that one of the EBV early proteins (MS-EA) behaves like adenovirus E1a and can transactivate the E4 promoter in a CAT assay. The complementation of mutant adenoviruses in EBV-transformed lymphocytes may help the rescue of new adenovirus serotypes in immunosuppressed patients.

Linker mutation scanning of the genes encoding the adenovirus type 5 terminal protein precursor and DNA polymerase

The replication of adenovirus DNA requires, in addition to several host factors, three virus-encoded proteins: a DNA binding protein, the precursor of the terminal protein (pTP), and a DNA polymerase (Ad pol). Ad pol and pTP form a tight complex that is necessary for the initiation step in DNA replication. To perform mutation scanning of the adenovirus type 5 pTP and Ad pol a series of in-frame linker insertions of a 12-mer oligonucleotide d(CCCATCGATGGG) were introduced into cloned viral DNA fragments containing coding sequences of these proteins. The insertions are located at recognition sites for several blunt end-cutting restriction endonucleases. Forty different sites were mutagenized and the mutated genes were transferred to a plasmid that contains the left 42% of the adenovirus genome. They were rebuilt into the viral genome by means of in vivo recombination between plasmid DNA and digested adenovirus DNA-TP complex. The resulting viral genomes were tested for viability and rescued virus was analyzed for the presence of the inserted linker oligonucleotide. This procedure resulted in recovery of a number of viable virus mutants with insertions in the pTP or Ad pol genes, all of which are phenotypically silent. The other mutations did not allow virus production. The positions of these apparent lethal codon insertion mutations were useful to identify regions of functional importance in both proteins. It can be concluded that the precursor-specific region of pTP plays an important role in virus multiplication.

Physical mapping of two temperature-sensitive adenovirus mutants affected in the DNA polymerase and DNA binding protein

We have determined the exact nature of two thermosensitive (ts) adenovirus mutants, H5ts19 and H5ts149, which map to different genes in the E2 transcription unit. The H5ts19 mutation appears to stem from a single base-pair change of A-T to G-C at position 1840 (numbering as in ref. 1), corresponding to codon 154 of the gene coding for DBP. This results in a glutamine-to-arginine change in the amino-terminal domain of the protein. H5ts19 is defective in a late stage of infection, during virus assembly. This phenotype strongly differs from that described for the limited number of known DBP mutants, indicating that DBP is not only functional during DNA replication, but also plays a role in the late phase of the infection cycle. The defect of the (N group) mutant H5ts149 affects the initiation of viral DNA replication. Marker rescue experiments followed by nucleotide sequence analysis of H5ts149 DNA revealed a single point mutation in the gene coding for the Ad pol. A transition of C-G to A-T at position 7563 (numbering as in ref. 2) changes amino acid residue 411 of Ad pol, a leucine residue, to phenylalanine. This mutation is located in a region conserved among various DNA polymerases, which suggests an important role of this domain in DNA replication.

Conserved region 3 of the adenovirus type 5 DNA-binding protein is important for interaction with single-stranded DNA

The adenovirus-encoded single-stranded DNA-binding protein (DBP) functions in viral DNA replication and several aspects of RNA metabolism. Previous studies (G. A. M. Neale and G. R. Kitchingman, J. Biol. Chem. 264:3153-3159, 1989) have defined three highly conserved regions in the carboxy-terminal domain of the protein (amino acids 178 to 186, 322 to 330, and 464 to 475) that may be involved in the binding of the protein to single-stranded DNA. We examined the role of conserved region 3 (464 to 475) by constructing nine classes of point mutants with from one to four amino acid changes. The point mutants were tested for their ability to assist adeno-associated virus DNA replication. All nine differed from wild-type DBP; seven were essentially nonfunctional, whereas two had 55 and 145%, respectively, of the wild-type DBP helper activity. Three of the mutants were found to be temperature sensitive, with significantly greater helper activity at 33 degrees C than at 37 degrees C. All nine mutants produced essentially wild-type levels of protein. One monoclonal antibody against the DBP, termed 2/4, did not immunoprecipitate the mutant DBPs as well as wild-type DBP, indicating either that the antibody recognized sequences around CR3 or that the conformation of the protein around the epitope recognized by 2/4 had changed. Two of the three temperature-sensitive DBP mutants bound to single-stranded DNA-cellulose with the same affinity as wild-type DBP at 4 degrees C; the remaining mutants all showed reduced affinity. These results demonstrated that many of the residues within conserved region 3 of the DBP are important for interaction of the protein with nucleic acid.

HeLa nuclear protein recognizing DNA termini and translocating on DNA forming a regular DNA-multimeric protein complex

Employing an exonuclease III protection assay we detected a protein in crude HeLa nuclear extracts binding, with apparent sequence specificity, to molecular ends of adenovirus type 2 (Ad2) DNA. This protein, designated nuclear factor IV (NFIV), was purified to homogeneity and was shown to be a hetero-dimer of 72,000 and 84,000 Mr. Binding to terminal Ad2 sequences was strongly enhanced by the presence of either of the sequence-specific DNA-binding proteins nuclear factor I and nuclear factor III. These proteins appeared to function as blockades for translocation of NFIV on DNA, thus producing apparent sequence specificity. In the absence of such a blockade, NFIV moved freely, without energy input, on any double-stranded DNA forming a regular DNA-multimeric protein complex as shown by methidiumpropyl EDTA footprinting and electron microscopy. Binding is completely dependent upon the presence of molecular ends. Evidence was obtained for a two-step mechanism in which termini are recognized by NFIV and used as a starting point for subsequent translocation. The possible functions of the protein in adenovirus DNA replication and in cellular processes requiring DNA termini are discussed.

Adenovirus DNA replication in vitro: duplication of single-stranded DNA containing a panhandle structure

Adenovirus DNA replicates by displacement of one of the parental strands followed by duplication of the displaced parental single strand (complementary strand synthesis). Displacement synthesis has been performed in a reconstituted system composed of viral and cellular proteins, employing either the viral DNA-terminal protein complex as template or linearized plasmids containing the origin. Previously, evidence was obtained that in vivo complementary strand synthesis requires formation of a panhandle structure originating from hybridization of the inverted terminal repeats. To study the conditions for complementary strand synthesis in vitro, we have constructed an artificial panhandle molecule that contains a double-stranded inverted terminal repetition (ITR) region and a single-stranded loop derived from the left and right terminal XmaI fragments of Ad2. Such a molecule appeared to be an efficient template and could initiate by the same protein-priming mechanism as double-stranded DNA, employing the precursor terminal protein. The efficiency of both types of template was comparable. Like for replication of the duplex molecule initiation of panhandle replication was stimulated by nuclear factors I and III, proteins that bind to specific double-stranded regions of the ITR. The Ad DNA-binding protein is essential and the 39 kDa C-terminal domain of this protein that harbors the DNA-binding properties is sufficient for its function. These results support the hypothesis that panhandle formation is required for duplication of the displaced strand.

The binding of in vitro synthesized adenovirus DNA binding protein to single-stranded DNA is stimulated by zinc ions

We have synthesized wild type DNA binding protein (DBP) of adenovirus type 5 (Ad5) and several truncated forms of this protein by a combination of in vitro transcription and translation. The proteins obtained were tested for binding to a single-stranded DNA-cellulose column. It could be shown that for binding of in vitro synthesized wild type DBP, it is necessary to add zinc ions to the in vitro translation system. Binding studies with the truncated proteins revealed that deletion of the carboxyl-terminal 46 amino acids abolishes DNA binding.

DNA synthesis in a mitochondrial lysate of Xenopus laevis oocytes. H strand replication in vitro

Conditions for efficient replication in vitro of mitochondrial DNA L strand into H strand products have been established. Gel electrophoresis and hybridization analyses of the products show that neosynthesized H strands are progressively elongated from the D-loop region, and some of them are synthesized as full-length molecules. Evidence for initiation of these H strands de novo is presented. In contrast, there is no detectable L strand synthesis in vitro in this system. This may prove useful for analyzing the distinct molecular mechanisms operating at OH and OL. Use of specific inhibitors indicates that DNA synthesis in the mitochondrial lysate in vitro requires DNA polymerase gamma. These observations support the conclusion that replication in vitro in this system closely resembles the first steps of mitochondrial DNA replication in vivo.

Enhanced processivity of nuclear matrix bound DNA polymerase alpha from regenerating rat liver

Translocation of DNA during in vitro DNA synthesis on nuclear matrix bound replicational assemblies from regenerating rat liver was determined by measuring the processivity (average number of nucleotides added following one productive binding event of the polymerase to the DNA template) of nuclear matrix bound DNA polymerase alpha with poly(dT).oligo(A)10 as template primer. The matrix-bound polymerase had an average processivity (28.4 nucleotides) that was severalfold higher than the bulk nuclear DNA polymerase alpha activity extracted during nuclear matrix preparation (8.9 nucleotides). ATP at 1 mM markedly enhanced the activity and processivity of the matrix-bound polymerase but not the corresponding salt-soluble enzyme. The majority of the ATP-dependent activity and processivity enhancement was completed by 100 microM ATP and included products ranging up to full template length (1000-1200 nucleotides). Average processivity of the net ATP-stimulated polymerase activity exceeded 80 nucleotides with virtually all the DNA products greater than 50 nucleotides. Release of nuclear matrix bound DNA polymerase alpha by sonication resulted in a loss of ATP stimulation of activity and a corresponding decrease in processivity to a level similar to that of the salt-soluble polymerase (6.8 nucleotides). All nucleoside di- and triphosphates were as effective as ATP. Stimulation of both activity and processivity by the nonhydrolyzable ATP analogues adenosine 5'-O-(3-thiotriphosphate), 5'-adenylyl imidodiphosphate, and adenosine 5'-O-(1-thiotriphosphate) further suggested that the hydrolysis of ATP is not required for enhancement to occur.(ABSTRACT TRUNCATED AT 250 WORDS)