Role of conserved residues in the activity of adenovirus preterminal protein

Catherine H. Botting1 and Ronald T. Hay1

Centre for Biomolecular Sciences, School of Biology, University of St Andrews, Biomolecular Sciences Building, North Haugh, St Andrews, Fife KY16 9ST, UK1

Author for correspondence: Ronald Hay. Fax +44 1334 462595. e-mail rth{at}st-andrews.ac.uk


   Abstract
Top
Abstract
Introduction
Methods
Results
Discussion
References
 
Preterminal protein (pTP) is a component of the preinitiation complex which forms at the adenovirus origin of DNA replication and acts as the protein primer during DNA synthesis. In order to determine the role of various regions of the molecule a series of 18 mutations was introduced into conserved motifs of pTP which were predicted to be surface exposed, and the mutants expressed in insect cells using a baculovirus expression system. Their ability to initiate DNA replication was assessed and the effect the mutations have on the individual interactions which contribute to the formation of the pre-initiation complex was determined. Classes of mutants could be identified which were unable to bind DNA or interact with the adenovirus DNA polymerase, but one class of mutants retained these activities and yet failed to initiate DNA replication. These mutants therefore identify regions of pTP required for different aspects of adenovirus DNA replication.


   Introduction
Top
Abstract
Introduction
Methods
Results
Discussion
References
 
The human adenovirus (Ad) genome is a linear double-stranded DNA molecule of 36000 bp with inverted terminal repeats (ITRs) which are of about 100 bp in Ad2 and Ad5. A terminal protein (TP) is covalently attached to the 5' end. Three viral proteins and two cellular transcription factors interact with the terminal 51 bp of the adenovirus genome, defined as ori, the origin of DNA replication (Hay & Russell, 1989 ), to form the preinitiation complex. In Ad2, limited initiation can occur with just the three viral proteins, preterminal protein (pTP), adenovirus DNA polymerase (Adpol) and DNA binding protein (DBP), and the terminal 18 bp of the genome, defined as the minimal origin of replication (Challberg & Rawlins, 1984 ). However, replication is more efficient in the presence of the two transcription factors nuclear factor I and nuclear factor III (NFI and NFIII) (Nagata et al., 1983 ; Pruijn et al., 1986 ) and a 50 bp origin of replication which contains the binding sites of NFI and NFIII. The evidence suggests the following model for adenovirus DNA replication. The origin of replication is first coated with DBP, which protects the DNA and interacts co-operatively with NFI to enhance its binding to a recognition site located between bp 25 and 39 (Cleat & Hay, 1989 ; Mul et al., 1990 ). NFIII also binds to a specific site in the origin of replication between bp 39 and 49 and the pTP–Adpol heterodimer is then recruited to the DNA, binding between bp 9 and 18. It is stabilized by interactions with the TP–DNA (Pronk & van der Vliet, 1993 ), between pTP and NFIII (van Leeuwen et al., 1997 ; Botting & Hay, 1999 ) and Adpol and NFI (Bosher et al., 1990 ; Chen et al., 1990 ; Mul et al., 1990 ). DNA replication is then initiated by an Adpol-catalysed protein priming mechanism in which a covalent bond is formed between the {alpha}-phosphoryl group of the terminal residue, dCMP, and the {beta}-hydroxyl group of a serine residue in pTP (Challberg et al., 1980 ). The 3'-hydroxyl group of the pTP–dCMP complex is then used as a primer for synthesis of the nascent strand by Adpol. Base pairing with the second GTA triplet of the template strand guides the synthesis of a pTP-trinucleotide, which then jumps back three bases to base-pair with the first triplet (also GTA), and synthesis then proceeds by displacing the non-template strand (King & van der Vliet, 1994 ). Dissociation of pTP from Adpol begins as the pTP-trinucleotide is formed and is almost complete by the time seven nucleotides have been synthesized (King et al., 1997 ). NFIII dissociates as the replication fork passes through the NFIII binding site (van Leeuwen et al., 1997 ).

Previous attempts to make mutations in pTP have been confined to linker insertion mutagenesis and deletion of residues from the N terminus of pTP (Fredman et al., 1991 ; Freimuth & Ginsberg, 1986 ; Pettit et al., 1989 ; Roovers et al., 1991 , 1993 ; Schaack et al., 1999 ). Introduction of such mutations into the virus genome and transfections into a pTP complementing cell line allowed the growth of virus containing these mutations. A number of the mutants made proved to be silent showing that it is possible to mutate pTP by the addition of insertions and maintain activity. However, many viruses containing these mutations were not infectious in non-complementing cell lines. The phenotypes of the remaining mutants indicated the important role of specific pTP regions in viral infectivity.

Although there is as yet no structural information available for pTP the domain organization of the protein and the roles of different regions of the protein have been elucidated (Webster et al., 1997a ). The sites of interaction of a panel of monoclonal antibodies raised against pTP were identified. These largely coincide with the regions most susceptible to proteolysis, thus defining domain junctions or relatively unstructured regions. The Adpol-binding region was mapped to the C-terminal 60 kDa of the protein, whilst the N-terminal portion was involved in DNA binding. However, other portions of the molecule contribute to the strength of the interactions. It was shown that conformational antibodies against pTP disrupted DNA binding and could displace Adpol, highlighting the importance of protein flexibility in the interactions of pTP.

Here we use site-directed mutagenesis of pTP to define the roles of individual amino acids, conserved between the various strains of adenovirus and predicted to be surface exposed, in DNA replication.


   Methods
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Abstract
Introduction
Methods
Results
Discussion
References
 
{blacksquare} Construction of mutants.
Digestion with BamHI of vector pVL1393 containing the Ad2 pTP gene released cDNA containing the Ad2 pTP gene followed by a portion of non-coding viral genome. The cDNA was cropped by recutting with KpnI to give the Ad2 pTP gene followed by 50 bp of non-coding viral sequence. This cDNA was inserted into the vector pGEM-3Z (Promega), in which the site-directed mutagenesis was performed. Mutations were introduced by a PCR method, using primers synthesized by Oswel (University of Southampton). Details of the mutations made are presented in Fig. 1. They consist of eight single point mutations, seven double point mutations, a deletion between amino acids (aa) 183 and 207, the region being replaced by a NotI site encoding three glycine residues and two N-terminal deletions of aa 1–175, to give iTP, and aa 1–349, to give TP respectively. A C-terminal deletion of aa 560–671 was obtained from H. Liu (University of St Andrews). Table 1 lists the primers used for the mutagenesis.



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Fig. 1. (A) Sequence alignments for the regions of interest from 15 pTP genes. The residues in bold indicate those mutated. (B) Schematic diagram of pTP showing, above the bar, the positions of the point mutations (solid dots), the deletion (hatched bar) and the truncations (arrows). Below the bar are indicated the Ad2 protease cleavage sites (solid arrowheads) which give rise to the iTP and TP molecules, the trypsin partial proteolysis cleavage sites (open arrowheads), the recognition sites for several of the monoclonal antibodies (labelled solid bars), the region of the nuclear localization signal and the catalytic serine.

 

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Table 1. Primers used in site-directed mutagenesis

 
For all mutations except the N-terminal deletions, a two-step PCR amplification procedure was utilized. PCR was performed using a forward primer designed to hybridize to the Ad2 pTP gene at a unique restriction site [primer 1 (BstEII), primer 2 (XhoI), primer 3 (BglII)] and a mutagenesis primer (primers 7–9 with primer 1, primers 10–20 with primer 2, primers 21–22 with primer 3). Likewise, PCR was performed on the complementary strand using primer 4 (XhoI), primer 5 (BglII) or primer 6 (KpnI) and a mutagenesis primer (primers 23–25 with primer 4, primers 26–36 with primer 5, primers 37–38 with primer 6). These PCR products were purified from agarose gels with a Qiagen gel extraction kit and used as template in a second round of PCR using primers 1 and 4, 2 and 5 or 3 and 6 as appropriate. The PCR product obtained was digested with the appropriate restriction enzymes (BstEII and XhoI for PCR products corresponding to mutations 137Y/A, 139R/A and aa 183–207 del, XhoI and BglII for PCR products corresponding to mutations 356–357RE/AA, 360R/A, 363T/A, 384–385RR/AA, 386–387RR/AA, 388–389RR/AA, 437–438EE/AA, 484–485EH/AA, 492Y/A, 520D/A and 529R/A, and BglII and KpnI for PCR products corresponding to mutations 589Q/A and 598–599DS/AA. These inserts were ligated into pGEM-3Z.Ad2pTP vector which had been digested with the appropriate restriction enzymes to release the non-mutated insert.

The N-terminal deletions of aa 1–175, giving iTP, and of aa 1–349, giving TP, were made by PCR using forward primers 39 and 40, containing a BamHI site, and reverse primer 6, containing a KpnI site. The PCR product was digested with BamHI and KpnI and ligated with cut pGEM-3Z vector. For all the mutants, the sequence of the inserted region was confirmed by automatic DNA sequencing (Alex Houston, St Andrews University DNA sequencing service).

The mutated genes were cut out of pGEM-3Z, using the restriction enzymes BamHI and EcoRI, and subcloned into the pFASTBAC vector cut with the same enzymes. Plasmid from positive clones was transformed into DH10BAC competent E. coli. Recombinant bacmid DNA was isolated from the positive clones and used to transfect Spodoptera frugiperda 9 (Sf9) cells and thus generate recombinant baculovirus, as described in the Bac-to-Bac baculovirus expression systems instruction manual.

{blacksquare} Expression of pTP and mutant proteins in insect cells.
Sf9 cells (1x107) were infected with the baculovirus and harvested after 96 h. Infected cells were collected by centrifugation, washed twice with PBS (10 ml) and stored at -70 °C until required.

Cells were resuspended in 25 mM HEPES–NaOH pH 8·0, 5 mM KCl, 0·5 mM MgCl2 containing protease inhibitors (Boehringer Mannheim) (1 ml) and incubated on ice for 5 min. The cells were lysed using a Dounce homogenizer and the nuclei collected by centrifugation. The cytoplasmic extract was removed and the nuclei resuspended in 25 mM HEPES–NaOH pH 8·0, 1 M NaCl, 1 mM DTT containing protease inhibitors (1 ml) and incubated on ice for 15 min. The extract was clarified by high-speed centrifugation and aliquots of both nuclear and cytoplasmic extracts were snap frozen and stored at -70 °C until required. The mutants were found to be at least partially nuclear, with the exception of the aa 1–349 N-terminal deletion (TP) which was totally cytoplasmic. As the nuclear extracts proved to be less sensitive to proteolysis and the protein was more soluble in high NaCl concentration conditions, nuclear extracts were used in preference to cytoplasmic extracts. However, in order to obtain stable TP and sufficient quantities of mutant 437–438EE/AA and the aa 560–671 C-terminal deletion, a whole cell extract was made by swelling the cells in 25 mM HEPES–NaOH pH 8·0, 1 M NaCl, 1 mM DTT containing protease inhibitors directly. Extracts were clarified each time before use. All experiments were performed in duplicate.

{blacksquare} Immunoblotting.
Samples, to which disruption buffer containing SDS and 2-mercaptoethanol was added, were denatured by heating at 100 °C for 2 min and fractionated by SDS–PAGE. The proteins were electrophoretically transferred (mini Trans-Blot cell, Bio-Rad) onto PVDF membrane. Membranes were incubated in blocking buffer (PBS containing 5% non-fat milk), which was used in all subsequent incubations, and then with primary antibody at the appropriate dilution. Anti-pTP monoclonal antibodies 5E3, 44E1, 7H1 and 3D11 (Webster et al., 1997a ) were used to detect pTP/mutant pTP and an antibody raised against a peptide corresponding to the C terminus of Adpol was used to detect Adpol (Webster et al., 1994 ). The membrane was washed with PBS containing 0·1% Tween 20, before antibody–antigen complexes were detected by incubation with HRP-conjugated anti-mouse or anti-rabbit antibodies, as appropriate, and, after further washing, an enhanced chemiluminescence (ECL) system.

{blacksquare} Initiation assay.
Purified DBP (500 ng), extract prepared as described in Parker et al. (1998) from baculovirus-infected Sf9 cells containing 50 ng Adpol, extract containing 50 ng pTP/mutant pTP (dialysed against 25 mM potassium acetate, pH 8·0, 0·1 M NaCl, 1 mM DTT) and 50 ng TP-DNA template were added together with the appropriate volume of 25 mM Bicine–NaOH pH 8·0, 2 mM DTT, 1 mM MnCl2, 0·15 mM ATP, 0·2 mg/ml BSA to give a final volume of 10 µl. To this was added [{alpha}-32P]dCTP (2·5 µCi, 3000 Ci/mmol) and the samples were incubated at 30 °C for 1 h. Micrococcal nuclease (1 U) and CaCl2 to 10 mM were added and the samples incubated for a further 30 min at 37 °C. The reaction was stopped by the addition of disruption buffer (SDS to 2% and 2-mercaptoethanol to 0·72 M) to the reactions and the samples were denatured at 100 °C for 2 min before analysis of the reaction products by fractionation in an SDS–polyacrylamide/DATD gel; radioactivity in the dried gel was detected by PhosphorImaging.

{blacksquare} DNA binding assay.
Extract containing 100 ng pTP/mutant pTP was added to ssDNA–Sepharose (20 µl, 50% slurry) in 1 ml buffer containing 1% BSA (Sigma), 0·1 M (or 0·2 M) NaCl, 25 mM HEPES–NaOH pH 8·0, 1 mM EDTA, 1 mM DTT, 0·05% NP40. After incubation at 4 °C with end-over-end mixing, the beads were washed once with the above buffer at the appropriate NaCl concentration, followed by three washes with the above buffer, excluding BSA, at the appropriate NaCl concentration. The samples were then transferred to fresh microcentrifuge tubes, the buffer removed and disruption buffer added. The samples were denatured by heating at 100 °C for 2 min and fractionated by SDS–PAGE followed by immunoblotting, using anti-pTP monoclonal antibodies 44E1 and 3D11 as primary antibodies.

{blacksquare} Adenovirus DNA polymerase binding assay.
Protein G–agarose beads (25 µl, 50% slurry), to which saturating levels of the monoclonal antibody 16H1 (or 3D11 in the case of the aa 183–207 deletion and the aa 1–349 deletion, TP) had been bound, were blocked with 1% BSA, 25 mM HEPES–NaOH pH 8·0, 0·4 M NaCl, 1 mM EDTA, 1 mM DTT, 0·05% NP40 by overnight incubation at 4 °C. Extract containing 600 ng pTP/mutant pTP was added and the samples incubated for a further 2 h at 4 °C. The beads were washed three times with the above buffer and transferred to fresh siliconized microcentrifuge tubes. Extract containing 500 ng Adpol was added and the beads incubated for 2 h. They were then washed once with the above buffer and three times with the above buffer excluding BSA. The beads were transferred to fresh microcentrifuge tubes and disruption buffer was added. After heating to 100 °C proteins were fractionated by SDS–PAGE, transferred to PVDF membrane and immunoblotted as described above. To assess Adpol binding, the membrane was probed with an anti-Adpol antibody as primary antibody and an anti-rabbit HRP conjugate as secondary antibody. To confirm that equal quantities of pTP/mutant pTP had bound to the beads, the membrane was stripped and reprobed with anti-pTP monoclonal antibodies and anti-mouse HRP conjugate.

{blacksquare} Partial proteolysis.
Extract containing 130 ng pTP/mutant pTP was dialysed against 25 mM potassium acetate, pH 8·0, 0·1 M NaCl, 1 mM DTT. Each sample was normalized for total protein content by the addition of uninfected extract or the above buffer to give final volumes of 35 µl. Modified trypsin (Promega) (10 ng) was added to each sample and the samples were incubated at room temperature for 20 min. The reaction was stopped by the addition of PMSF (2·5 µl, 50 mM). Disruption buffer was added and the samples denatured by boiling and fractionated by SDS–PAGE. The protein was transferred to PVDF and immunoblotted as described above, using monoclonal antibodies 3D11 and 44E1 as primary antibodies.


   Results
Top
Abstract
Introduction
Methods
Results
Discussion
References
 
Construction and expression of pTP mutants
The amino acid sequences of pTP from human adenoviruses 2, 5, 7, 4, 12 and 40, canine adenoviruses 1 and 2, bovine adenoviruses 2 and 3, murine adenovirus 1, ovine adenovirus and the avian CELO and EDS adenoviruses were aligned and conserved amino acids identified (Fig. 1A). Using the Predict-Protein program (Rost & Sander, 1993 ) residues likely to be exposed were identified. As these residues are likely to participate in the interactions of pTP with other molecules, a series of 15 point mutations and 3 deletion mutations was constructed (Fig. 1B). In each of the point mutations the amino acids were changed to alanine. The aa 183–207 deletion corresponds to the removal of a region present in Ad2/5 but absent in Ad4. It was therefore of interest to see if any Ad4-like properties were conferred on this mutant. The N-terminal deletions (aa 1–175 and aa 1–349) gave the molecules generated by Ad2 protease digestion, namely iTP and TP respectively. A C-terminal deletion of aa 560–671 was obtained from H. Liu (University of St Andrews).

The mutations were constructed by PCR methodologies and transferred into bacmids which were used to generate recombinant baculovirus. Sf9 cells infected with recombinant baculovirus were harvested 96 h post-infection and nuclear and cytoplasmic extracts prepared. All mutants were predominantly nuclear, except the aa 1–349 deletion (TP) which was totally cytoplasmic. The nuclear localization sequence (NLS) of pTP has previously been mapped to amino acids 380–391 (Zhao & Padmanabhan, 1988 ), although the minimum sequence required for nuclear localization was not determined. The deletion giving TP, therefore, includes the NLS but is not transported into the nucleus in insect cells. The mutants 384–385RR/AA, 386–387RR/AA and 388–389RR/AA have double point mutations of consecutive arginines within the predicted NLS but do not have their nuclear localization disrupted to any great degree.

As pTP was not expressed at the same level for each mutant, dilutions of cell extract from each recombinant baculovirus infection were analysed by immunoblotting using the anti-pTP monoclonal antibodies 44E1 and 3D11 (Fig. 2), and volumes of extract adjusted so that equivalent amounts of pTP mutants were added to each assay. The 484–485EH/AA mutant was not expressed efficiently and therefore was not studied further.



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Fig. 2. Immunoblot of extracts expressing pTP/mutant pTP. All extracts are nuclear unless otherwise stated. Extracts of: wild-type pTP (1 µl), 137Y/A (4 µl), 139R/A (4 µl), aa 183–207 del (14 µl), 356–357RE/AA (2 µl), 360R/A (2 µl), 363T/A (4 µl), 384–385RR/AA (6 µl), 386–387RR/AA (3 µl), 388–389RR/AA (4 µl), 437–438EE/AA (4 µl, w.c.e.), 484–485EH/AA (20 µl), 492Y/A (20 µl), 520D/A (5 µl), 529R/A (6 µl), 589Q/A (3 µl), 598–599DS/AA (5 µl), aa 560–671 C-terminal deletion (15 µl, w.c.e.), TP (aa 1–349 N-terminal deletion) (15 µl, w.c.e.) and iTP (aa 1–175 N-terminal deletion) (4 µl) were fractionated by SDS–PAGE and transferred to PVDF membrane. The blot was probed with anti-pTP monoclonal antibodies 44E1 and 3D11.

 
Monoclonal antibody 44E1 was shown to recognize each of the mutants, by immunoblotting, whilst 3D11 recognized all but the aa 560–671 deletion. This monoclonal antibody binds close to the C terminus of pTP, which is not present in this truncation. Predictably, monoclonal antibody 5E3 did not recognize the aa 183–207 deletion, which is indeed a deletion of its epitope, previously mapped to aa 186–200 (Webster et al., 1997a ; Botting & Hay, 1999 ). Monoclonal antibody 7H1, which had been mapped to a region between aa 388 and 607 (Webster et al., 1994 ), recognized all the mutants except 492Y/A and the C-terminal deletion, but in an immunoblot recognized 520D/A, 529R/A, 589Q/A and 598–599DS/AA with reduced affinity compared to the other mutants (data not shown). This would suggest that the epitope for 7H1 is not linear and contains determinants that include 492Y and regions towards the C terminus.

Ability of pTP mutants to initiate DNA replication
The ability of mutant forms of pTP to participate in viral DNA replication was determined in an in vitro initiation assay. Extract containing pTP/mutant pTP was added to an assay containing the TP–viral DNA template containing the origin of replication, DBP, Adpol, Mg, ATP and dCTP. Initiation involves the Adpol-catalysed addition of [32P]dCMP to pTP. The production of [32P]pTP–dCMP was assessed by separating the labelled protein from free nucleotide by SDS–PAGE and analysis by autoradiography (Fig. 3). All mutants were defective for initiation compared to wild-type pTP. The mutants 356–357RE/AA, 360R/A, 386–387RR/AA, 520D/A and 589Q/A were reasonably efficient at initiation. Mutants 137Y/A, 139R/A, aa 183–207 del, 363T/A, 388–389RR/AA, 529R/A and 598–599DS/AA initiated very weakly, while mutants 384–385RR/AA, 437–438EE/AA, 492Y/A, the C-terminal deletion, iTP (aa 1–175 del) and TP (aa 1–349 del) appeared not to support initiation. These results are summarized in Table 2. Although NFIII was not added specifically to the reaction, it was expected to be present in the added extract. However, it is important to note that at the high pTP/pol concentration used the stimulatory effect of NFIII would not be observed (Coenjaerts et al., 1994 ). Hence, the ability of the mutants to bind NFIII does not seem to play a major role in determining the efficiency by which they initiate adenovirus DNA replication.



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Fig. 3. Initiation assay. DBP (500 ng), extract containing 50 ng Adpol, extract containing 50 ng pTP/mutant pTP and 50 ng TP–DNA template were incubated in ATP-containing buffer. [{alpha}-32P]dCTP was added and the samples incubated at 30 °C for 1 h. Further incubation with micrococcal nuclease and CaCl2 destroyed the template. Disruption buffer was added and the samples boiled for 2 min before fractionation by SDS–PAGE. The dried gel was subjected to PhosphorImaging and autoradiography.

 

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Table 2. Phenotypes of pTP mutants

 
To determine why the mutants were defective for initiation of DNA replication, their ability to participate in interactions involved in the formation of the pre-initiation complex was assessed.

Interaction of pTP mutants with ssDNA
The ability of the mutants to bind to ssDNA–Sepharose was assessed in the presence of either 0·1 or 0·2 M NaCl. Extracts were incubated with ssDNA–Sepharose at the two NaCl concentrations and bound pTP was detected by immunoblotting (Fig. 4). All mutants bound DNA in 0·1 M NaCl, but carrying out the binding assay in 0·2 M NaCl allowed discrimination between the various mutants and identified some that were no longer able to bind to DNA. Those that did not bind at 0·2 M were 384–385RR/AA, 386–387RR/AA, 388–389RR/AA and iTP (aa 1–175 del). For all the mutants except 356–357RE/AA there was a reduction in binding activity in 0·2 M NaCl when compared to 0·1 M NaCl whereas wild-type pTP bound DNA with comparable efficiency at both NaCl concentrations. Although stability of the pTP–DNA interaction to increasing concentrations of NaCl may not be a true measure of binding affinity, it is expected that mutants which retain DNA binding activity at the higher NaCl concentration have a greater affinity for DNA. These results are summarized in Table 2.



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Fig. 4. ssDNA binding assay. Extract containing 100 ng pTP/mutant pTP was incubated with ssDNA–Sepharose at 0·1 or 0·2 M NaCl. After thoroughly washing the beads, disruption buffer was added, the samples denatured by heating at 100 °C for 2 min and fractionated by SDS–PAGE. Immunoblotting was used to detect the bound pTP/mutant pTP.

 
Interaction of pTP mutants with Adpol
The ability of the pTP mutants to interact with Adpol was assessed by measuring the binding of Adpol to protein G–agarose beads on which the pTP mutants had been immobilized, via the monoclonal antibody 16H1 (or 3D11 for aa 183–207 deletion and the aa 1–349 deletion, TP). These antibodies had been previously shown not to block the pTP–Adpol interaction (Webster et al., 1997a ). Bound Adpol was detected by immunoblotting, using an anti-Adpol polyclonal antibody. Reprobing with anti-pTP monoclonal antibodies was used to ensure that equal quantities of pTP/mutant pTP were immobilized in each experiment (Fig. 5). All the mutants were found to be defective in Adpol binding compared to wild-type pTP. The mutants binding Adpol most strongly were aa 183–207 deletion, 356–357RE/AA, 529R/A and 589Q/A. Mutants binding Adpol with intermediate activity were 137Y/A, 139R/A, 363T/A, 384–385RR/AA, 388–389RR/AA and 437–438EE/AA. Mutants 360R/A, 520D/A, 598–599DS/AA bound Adpol very weakly. Binding of the N-terminal deletions, giving iTP and TP, to Adpol could not be detected. These results are summarized in Table 2. 492Y/A and the C-terminal deletion were not tested in this assay because not enough material could be obtained as they were not expressed at high enough levels.



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Fig. 5. Adenovirus DNA polymerase binding assay. Extract containing 600 ng pTP/mutant pTP was incubated with monoclonal antibody 16H1 (or 3D11 where appropriate) immobilized on protein G–agarose beads. The beads were washed and extract containing Adpol 500 ng added. After incubation, the beads were washed, disruption buffer added and the samples boiled. After separation by SDS–PAGE the samples were immunoblotted and probed for (A) bound Adpol, (B) pTP.

 
Structural integrity of pTP mutants
The partial proteolysis of wild-type pTP with trypsin gives cleavage at specific sites in pTP which have previously been mapped (Webster et al., 1997a ; Botting & Hay, 1999 ). Extracts containing the mutant pTP were dialysed to remove protease inhibitors and to reduce the NaCl concentration, which has previously been shown to allow pTP to adopt a less compact conformation. They were then subjected to partial proteolysis. Proteolytic products were detected by immunoblotting (Fig. 6). Species at 68 and 40 kDa are due to trypsin proteolysis, while the 55 kDa product is generated in the absence of trypsin and is due to endogenous proteolytic activity in the cell extract. None of the mutants was highly susceptible to proteolysis and no digestion products were detected with the mutants that were not present in the wild-type pTP digest. Thus, none of the mutations appear to substantially destabilize the structure of pTP. In fact, most mutants were less susceptible to proteolysis than wild-type pTP. Of the mutants, 356–357RE/AA and 437–438EE/AA showed the largest degree of digestion, followed by 137Y/A and 386–387RR/AA. Mutants 139R/A, 360R/A, 388–389RR/AA, 520D/A, 529R/A, 598–599DS/AA were digested slightly during the time period of the experiment. Mutants 363T/A, 384–385RR/AA, 492Y/A, aa 183–207 del and aa 1–175 del (iTP) were resistant to digestion during this time period. The aa 183–207 deletion lacks the 67 kDa cleavage site but blocking digestion at this site has been shown not to preclude digestion at the 40 kDa site (Botting & Hay, 1999 ), which is present in this mutant but not cleaved.



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Fig. 6. Partial proteolysis of pTP/mutant pTP. Extract containing 130 ng pTP/mutant pTP was digested with trypsin (10 ng) at room temperature for 20 min. The reaction was stopped by addition of PMSF, disruption buffer was added and the samples denatured by boiling and fractionated by SDS–PAGE. The digestion products were detected by immunoblotting.

 

   Discussion
Top
Abstract
Introduction
Methods
Results
Discussion
References
 
The role played by pTP in the initiation of adenovirus DNA replication is crucial and complex. In the pre-initiation complex, it participates in multiple molecular interactions and makes direct contacts with Adpol, TP, NFIII and its DNA recognition site. The preinitiation complex comes together on the origin of replication in such a way that the pTP primer is correctly orientated with respect to Adpol. This ensures that serine-580 in pTP is accessible to the Adpol catalytic site and the DNA template to react with the first nucleotide to be added, dCTP to give dCMP, in the protein priming reaction. Therefore, any mutations in pTP which affect the positioning of this residue are likely to have a detrimental effect on initiation. The pTP molecule is highly conserved between adenovirus serotypes, suggesting crucial roles for much of the protein. Residues targeted for mutation are located in these conserved regions and were predicted to be surface exposed. It was, therefore, expected that while these mutations might have dramatic effects on the initiation process, they would not disrupt the structural integrity of pTP. The resistance of all mutants to trypsin digestion suggests that this is indeed the case.

All of the mutants generated are compromised to some extent in their ability to interact with Adpol and DNA. Of the 18 mutants tested 13 were severely compromised for initiation activity and all of the mutants displayed a reduced ability to participate in the initiation reaction. The data are summarized in Table 2.

Mutants such as 137Y/A, 139R/A, aa 183–207 del, 437–438EE/AA and 529R/A bind both Adpol and DNA reasonably well, but are severely compromised in their ability to participate in the initiation of DNA replication. These mutants are presumably incorporated into the preinitiation complex but fail to act as a primer onto which Adpol can transfer dCMP. Possible explanations for this behaviour are that the hydroxyl group of serine-580 is not precisely aligned in the active site of Adpol and as such fails to prime DNA replication. Alternatively, pTP may have to undergo a conformational change during the initiation process and the mutants may be defective in this step.

Mutant 356–357RE/AA shows the most initiation activity after wild-type pTP. This mutant binds DNA well at 0·2 M NaCl and also binds to Adpol. Two mutants which also display initiation activity are 360R/A and 589Q/A. Both mutants bind DNA reasonably well, although 589Q/A binds to Adpol much more strongly than 360R/A does. The strength of pTP binding to Adpol does not seem to be a major determinant in initiation activity. Mutants 137Y/A, 139R/A, 363T/A, 384–385RR/AA, 388–389RR/AA and 529R/A all bind to Adpol reasonably well but all show barely detectable or no initiation. Conversely, mutants 386–387RR/AA and 598–599DS/AA display some of the weakest DNA binding at 0·2 M NaCl but are the next most active for initiation after 356–357RE/AA, 360R/A and 589Q/A. It can therefore be seen that the initiation process is controlled by more subtle effects than just the strength of interaction with members of the complex. It is expected that small changes in these interactions, possibly brought about by conformational changes induced in pTP have a major effect on activity by altering the position of serine-580, the catalytic serine.

A number of the mutants in the central portion of pTP have compromised DNA binding activity, indicating that this region of the molecule is involved in interaction with DNA. The N-terminal deletions aa 1–175 del (iTP) and aa 1–349 del (TP) are compromised for DNA binding in 0·2 M NaCl. This is consistent with previous work (Webster et al., 1997b ) which demonstrated that TP and iTP generated in situ by the Ad2 protease were defective for DNA binding. On the basis of UV cross-linking experiments it was previously demonstrated that the N-terminal region of pTP was in contact with DNA (Webster et al., 1997a ). However, mutants in the N-terminal region (137Y/A and 139R/A) retain DNA binding activity, indicating that these particular residues are not directly involved in interaction with DNA. In addition, it was demonstrated (Webster et al., 1997a ) that antibodies binding to other regions of the molecule disrupted the interaction with the DNA, suggesting that regions of pTP other than the N-terminal portion of the molecule are required for efficient DNA binding. This is supported by the present mutational analysis.

In vivo, pTP exists in a stable complex with Adpol and high concentrations of denaturant (1·7 M urea) are required to separate the subunits. The Adpol binding assay shows that there are multiple regions of the pTP molecule which appear to bind to Adpol. This is consistent with the partial proteolysis experiments (Webster et al., 1997a ) which showed Adpol protecting a region between the iTP and TP cleavage sites, the TP cleavage site itself and a portion of the C terminus. Here, the residues in this region involved in the interaction may be defined more specifically, as mutants 520D/A and 598–599DS/AA are very poor at binding Adpol whereas mutants 529R/A and 589Q/A are relatively efficient at binding Adpol. Thus, it seems likely that a large proportion of the pTP surface contributes to the interface with Adpol.

It was predicted that the aa 183–207 region might form an exposed loop. Ad4 pTP lacks this region and so it was thought that the mutant with a deletion in this region might mimic Ad4 pTP. However, the deletion mutant was found to initiate DNA replication very inefficiently suggesting that the putative loop region is important for pTP initiation activity. Whether Ad4 pTP manages to circumvent the requirement for this loop, through alterations in other parts of its structure remains unclear.

The aa 1–175 (iTP) and aa 1–349 (TP) deletions are both unable to initiate. This contrasts with data obtained using iTP produced by in situ digestion with Ad2 protease, where iTP was shown to be efficient at initiation (Webster et al., 1997b ). However, in this experiment it was shown that the cleaved N-terminal portion of pTP remained associated with iTP in that both portions could be co-immunoprecipitated with Adpol. The genetically generated iTP did not bind Adpol which suggests that the N-terminal and iTP portions of pTP need to be associated for Adpol binding and initiation to occur. TP produced by Ad2 protease digestion does not remain associated with the cleaved N-terminal portions and does not bind Adpol or support initiation. These results are in agreement with those obtained using the aa 1–349 deletion (TP).

It was noted that the aa 1–349 deletion (TP), although it contained the NLS (Zhao & Padmanabhan, 1988 ), was exclusively cytoplasmic. This may highlight a difference in the NLS requirements of insect cells. On the other hand, it may suggest that the NLS is not surface exposed in the baculovirus-expressed TP. Thus, an individual TP molecule may be adopting a conformation different to that adopted by the TP portion of pTP. The mutants 384–385RR/AA, 386–387RR/AA and 388–389RR/AA are still transported to the nucleus although they contain double mutations of arginines to alanines within the NLS. It would, therefore, seem likely that some of the arginines in the NLS are redundant, as predicted from the sequence alignment which shows variations in the number and position of conserved arginines in the more distantly related adenovirus serotypes.

The mutants analysed in this study shed light on the requirements of pTP in different aspects of adenovirus replication and identify regions of pTP associated with these activities.


   Acknowledgments
 
We would like to thank H. Liu for the C-terminal deletion construct and for useful discussions. The DNA sequencing was carried out by Alex Houston. This work was supported by the Caledonian Research Foundation/Royal Society of Edinburgh.


   References
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Abstract
Introduction
Methods
Results
Discussion
References
 
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Received 27 March 2001; accepted 10 May 2001.