Mutations of the precursor to the terminal protein of adenovirus serotypes 2 and 5

Engineered Sleeping Beauty Transposon as Efficient System to Optimize Chimp Adenoviral Production

Sleeping Beauty (SB) is the first DNA transposon employed for efficient transposition in vertebrate cells, opening new applications for genetic engineering and gene therapies. A transposon-based gene delivery system holds the favourable features of non-viral vectors and an attractive safety profile. Here, we employed SB to engineer HEK293 cells for optimizing the production of a chimpanzee Adenovector (chAd) belonging to the Human Mastadenovirus C species. To date, chAd vectors are employed in several clinical settings for infectious diseases, last but not least COVID-19. A robust, efficient and quick viral vector production could advance the clinical application of chAd vectors. To this aim, we firstly swapped the hAd5 E1 with chAd-C E1 gene by using the CRISPR/Cas9 system. We demonstrated that in the absence of human Ad5 E1, chimp Ad-C E1 gene did not support HEK293 survival. To improve chAd-C vector production, we engineered HEK293 cells to stably express the chAd-C precursor terminal protein (ch.pTP), which plays a crucial role in chimpanzee Adenoviral DNA replication. The results indicate that exogenous ch.pTP expression significantly ameliorate the packaging and amplification of recombinant chAd-C vectors thus, the engineered HEK293ch.pTP cells could represent a superior packaging cell line for the production of these vectors.

The adenovirus priming protein pTP contributes to the kinetics of initiation of DNA replication

Adenovirus (Ad) precursor terminal protein (pTP) in a complex with Ad DNA polymerase (pol) serves as a primer for Ad DNA replication. During initiation, pol covalently couples the first dCTP with Ser-580 of pTP. By using an in vitro reconstituted replication system comprised of purified proteins, we demonstrate that the conserved Asp-578 and Asp-582 residues of pTP, located close to Ser-580, are important for the initiation activity of the pTP/pol complex. In particular, the negative charge of Asp-578 is essential for this process. The introduced pTP mutations do not alter the binding capacity to DNA or polymerase, suggesting that the priming mechanism is affected. The Asp-578 or Asp-582 mutations increase the Km for dCTP incorporation, and higher dCTP concentrations or Mn2+ replacing Mg2+ partially relieve the initiation defect. Moreover, the kcat/Km values are reduced as a consequence of the pTP mutations. These observations demonstrate that pTP influences the catalytic activity of pol in initiation. Since both Asp residues are situated close to the pol active site during initiation, they may contribute to correct positioning of the OH group in Ser-580. Our results indicate that specific amino acids of the protein primer influence the ability of Ad5 DNA polymerase to initiate DNA replication.

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.

Replacement of the P1 amino acid of human immunodeficiency virus type 1 Gag processing sites can inhibit or enhance the rate of cleavage by the viral protease

Processing of the human immunodeficiency virus type 1 (HIV-1) Gag precursor is highly regulated, with differential rates of cleavage at the five major processing sites to give characteristic processing intermediates. We examined the role of the P1 amino acid in determining the rate of cleavage at each of these five sites by using libraries of mutants generated by site-directed mutagenesis. Between 12 and 17 substitution mutants were tested at each P1 position in Gag, using recombinant HIV-1 protease (PR) in an in vitro processing reaction of radiolabeled Gag substrate. There were three sites in Gag (MA/CA, CA/p2, NC/p1) where one or more substitutions mediated enhanced rates of cleavage, with an enhancement greater than 60-fold in the case of NC/p1. For the other two sites (p2/NC, p1/p6), the wild-type amino acid conferred optimal cleavage. The order of the relative rates of cleavage with the P1 amino acids Tyr, Met, and Leu suggests that processing sites can be placed into two groups and that the two groups are defined by the size of the P1' amino acid. These results point to a trans effect between the P1 and P1' amino acids that is likely to be a major determinant of the rate of cleavage at the individual sites and therefore also a determinant of the ordered cleavage of the Gag precursor.

Role of conserved residues in the activity of adenovirus preterminal protein

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.

Role of preterminal protein processing in adenovirus replication

Preterminal protein (pTP), the protein primer for adenovirus DNA replication, is processed at two sites by the virus-encoded protease to yield mature terminal protein (TP). Here we demonstrate that processing to TP, via an intermediate (iTP), is conserved in all serotypes sequenced to date; and in determining the sites cleaved in Ad4 pTP, we extend the previously published substrate specificity of human adenovirus proteases to include a glutamine residue at P4. Furthermore, using monoclonal antibodies raised against pTP, we show that processing to iTP and TP are temporally separated in the infectious cycle, with processing to iTP taking place outside the virus particles. In vitro and in vivo studies of viral DNA replication reveal that iTP can act as a template for initiation and elongation and argue against a role for virus-encoded protease in switching off DNA replication. Virus DNA with TP attached to its 5' end (TP-DNA) has been studied extensively in in vitro DNA replication assays. Given that in vivo pTP-DNA, not TP-DNA, is the template for all but the first round of replication, the two templates were compared in vitro and shown to have different properties. Immunofluorescence studies suggest that a region spanning the TP cleavage site is involved in defining the subnuclear localization of pTP. Therefore, a likely role for the processing of pTP-DNA is to create a distinct template for early transcription (TP-DNA), while the terminal protein moiety, be it TP or pTP, serves to guide the template to the appropriate subcellular location through the course of infection.

Bipartite structure and functional independence of adenovirus type 5 packaging elements

Selectivity and polarity of adenovirus type 5 DNA packaging are believed to be directed by an interaction of putative packaging factors with the cis-acting adenovirus packaging domain located within the genomic left end (nucleotides 194 to 380). In previous studies, this packaging domain was mutationally dissected into at least seven functional elements called A repeats. These elements, albeit redundant in function, exhibit differences in the ability to support viral packaging, with elements I, II, V, and VI as the most critical repeats. Viral packaging was shown to be sensitive to spatial changes between individual A repeats. To study the importance of spatial constraints in more detail, we performed site-directed mutagenesis of the 21-bp linker regions separating A repeats I and II, as well as A repeats V and VI. The results of our mutational analysis reveal previously unrecognized sequences that are critical for DNA encapsidation in vivo. On the basis of these results, we present a more complex consensus motif for the adenovirus packaging elements which is bipartite in structure. DNA encapsidation is compromised by changes in spacing between the two conserved parts of the consensus motif, rather than between different A repeats. Genetic evidence implicating packaging elements as independent units in viral DNA packaging is derived from the selection of revertants from a packaging-deficient adenovirus: multimerization of packaging repeats is sufficient for the evolution of packaging-competent viruses. Finally, we identify minimally sized segments of the adenovirus packaging domain that can confer viability and packaging activity to viruses carrying gross truncations within their left-end sequences. Coinfection experiments using the revertant as well as the minimal-packaging-domain mutant viruses strengthen existing arguments for the involvement of limiting, trans-acting components in viral DNA packaging.

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.

Adenovirus type 5 precursor terminal protein-expressing 293 and HeLa cell lines

HeLa and 293 cell lines that express biologically active adenovirus type 5 precursor terminal protein (pTP) have been made. The amount of pTP synthesized in these cell lines ranges from barely detectable to greater than that observed in cells infected with the wild-type virus. The pTP-expressing cell lines permit the growth of a temperature-sensitive terminal protein mutant virus sub100r at the nonpermissive temperature. A higher percentage of the stably transfected 293 cell lines expressed terminal protein, and generally at considerably higher levels, than did the HeLa cell lines. While 293 cells appeared to tolerate pTP better than did HeLa cells, high-level pTP expression in 293 cells led to a significantly reduced growth rate. The 293-pTP cell lines produce infectious virus after transfection with purified viral DNA and form plaques when overlaid with Noble agar after infection at low multiplicity. These cell lines offer promise for the production of adenoviruses lacking pTP expression and therefore completely defective for replication.

The p2 domain of human immunodeficiency virus type 1 Gag regulates sequential proteolytic processing and is required to produce fully infectious virions

The proteolytic processing sites of the human immunodeficiency virus type 1 (HIV-1) Gag precursor are cleaved in a sequential manner by the viral protease. We investigated the factors that regulate sequential processing. When full-length Gag protein was digested with recombinant HIV-1 protease in vitro, four of the five major processing sites in Gag were cleaved at rates that differ by as much as 400-fold. Three of these four processing sites were cleaved independently of the others. The CA/p2 site, however, was cleaved approximately 20-fold faster when the adjacent downstream p2/NC site was blocked from cleavage or when the p2 domain of Gag was deleted. These results suggest that the presence of a C-terminal p2 tail on processing intermediates slows cleavage at the upstream CA/p2 site. We also found that lower pH selectively accelerated cleavage of the CA/p2 processing site in the full-length precursor and as a peptide primarily by a sequence-based mechanism rather than by a change in protein conformation. Deletion of the p2 domain of Gag results in released virions that are less infectious despite the presence of the processed final products of Gag. These findings suggest that the p2 domain of HIV-1 Gag regulates the rate of cleavage at the CA/p2 processing site during sequential processing in vitro and in infected cells and that p2 may function in the proper assembly of virions.

Activation of adenovirus-coded protease and processing of preterminal protein

Adenoviruses code for a protease that is essential for infectivity and is activated by a disulfide-linked peptide, derived from the C terminus of the virus structural protein pVI (pVI-CT). The protease was synthesized at relatively high levels late in infection and was detected in both cytoplasmic and nuclear fractions of adenovirus-infected cells. DNA was not found to be a cofactor of the protease, as previously proposed (W. F. Mangel, W. J. McGrath, D. Toledo, and C. W. Anderson, Nature [London] 361:274-275, 1993), but a role for DNA in facilitating the activation of the protease by pVI-CT in vivo cannot be ruled out. Adenovirus preterminal protein is a substrate for the virus-coded protease, with digestion to the mature terminal protein proceeding via the formation of two intermediates. Each of the three cleavage sites in the preterminal protein was identified by N-terminal sequencing and shown to conform to the substrate specificity of adenovirus protease, (M,L,I)XGX-X. Functional studies revealed that preterminal protein and intermediates but not mature terminal protein associated with adenovirus polymerase, while only the intact preterminal protein and none of its digestion products bound to DNA. These results suggest that the virus-coded protease may influence viral DNA replication by cleavage of both genome-bound and freely soluble preterminal protein, with consequent alterations to their functional properties.

Reverse transcription in hepatitis B viruses is primed by a tyrosine residue of the polymerase

All known DNA polymerases require primers for the initiation of DNA synthesis. While cellular polymerases and reverse transcriptases use free hydroxyl groups of RNA or DNA, the DNA polymerases of certain animal viruses and bacteriophages depend upon hydroxyl groups of amino acid residues within proteins as primers for DNA synthesis. Recently, the reverse transcriptase of a hepadnavirus has been shown to prime RNA-directed DNA synthesis from an internal site of the polypeptide (G.H. Wang and C. Seeger, Cell 71:663-670, 1992). In this report we demonstrate that a tyrosine residue of the polymerase polypeptide is the site of a phosphodiester linkage with the first nucleotide of minus-strand DNA. This tyrosine residue is located within an amino-terminal domain of the polymerase polypeptide and is indispensable for the priming of reverse transcription. Our results demonstrate that the hepatitis B virus reverse transcriptase can initiate DNA synthesis without the requirement for tRNA as a primer.

Adenovirus precursor to terminal protein interacts with the nuclear matrix in vivo and in vitro

The adenovirus precursor to the terminal protein (pTP), expressed in a vaccinia virus expression system or in native adenovirus, was assayed for its ability to interact with the nuclear matrix. Biochemical function was measured by determining the relative amount of pTP protein or of adenovirus DNA that remained associated with the nuclear matrix after extensive washing. pTP was retained on the matrix whereas beta-galactosidase was not, as assayed by quantitative immunoblot analysis. Nuclear matrix isolated from adenovirus-infected HeLa cells retained bound adenovirus DNA even when washed with 1 M guanidine hydrochloride; this interaction could be inhibited by added purified pTP protein. Analogous experiments with matrix isolated from HeLa cells infected with a recombinant vaccinia virus that expressed pTP showed a similar retention of pTP protein; this association could also be inhibited by added pTP protein. Binding of pTP to nuclear matrix isolated from uninfected cells was saturable, with an apparent Kd of 250 nM and an estimated 2.8 x 10(6) sites for pTP binding per cell nucleus. The association of pTP with matrix is postulated to help direct adenovirus replication complexes to the appropriate locale within the nucleus.

The adenovirus terminal protein influences binding of replication proteins and changes the origin structure

The adenovirus terminal protein (TP) is covalently linked to the 5' ends of the adenovirus genome and enhances DNA replication in vitro by increasing template activity. To study the effect of TP in more detail we isolated short origin fragments containing functional TP using anion exchange chromatography. These fragments were highly active as templates for DNA replication in a reconstituted system. Employing band-shift assays we found that the affinity of the precursor terminal protein-DNA polymerase complex for the TP-containing origin was increased 2 to 3-fold. Binding affinities of two other replication stimulating proteins, NFI and Oct-1, were not influenced by the terminal protein. Upon DNaseI footprinting we observed, unexpectedly, that the breakdown pattern had changed at various positions in the origin, notably in the area 3-6 and 41-51 by the presence of TP. Some differences in the footprint pattern of NFI and Oct-1 were also found. Our results indicate that TP induces subtle changes in the origin structure that influence the interaction of other replication proteins.

Analysis of the adenovirus type 5 terminal protein precursor and DNA polymerase by linker insertion mutagenesis

A series of adenovirus type 5 precursor terminal protein (pTP) and DNA polymerase (Ad pol) genes with linker insertion mutations were separately introduced into the vaccinia virus genome under the control of a late vaccinia virus promoter. The recombinant viruses were used for overexpression of the mutant genes in HeLa cells. In total, 22 different mutant pTP and 10 different Ad pol vaccinia virus recombinants were constructed, including some that expressed carboxyl-terminus-truncated forms of both proteins and one that produced the mutant H5ts149 Ad pol. To investigate the structure-function relationships of both proteins, extracts from cells infected with the recombinant viruses were tested for in vitro complementation of the initiation and elongation steps in adenovirus DNA replication. The results were in accordance with those of earlier in vivo experiments with these insertion mutants and indicate that multiple regions of both proteins are essential for adenovirus DNA replication. The carboxyl termini of both pTP and Ad pol were shown to be essential for proper functioning of these proteins during initiation of adenovirus DNA replication. Three different DNA replication-negative pTP mutants were shown to have residual activity in the initiation assay, suggesting not only that pTP is required for initiation but also that it may play a role in DNA replication after the deoxycytidylation step.

Adenovirus DNA replication: the function of the covalently bound terminal protein

Initiation of Adenovirus DNA replication in vitro requires the presence of three viral proteins (pTP, pol, DBP) and two cellular transcription factors, NFI and Oct-1, that stimulate replication more than 100-fold. NFI assists in binding and positioning of the DNA polymerase in the origin whereas Oct-1 changes the structure of origin DNA. Optimal templates contain, in addition to origin sequences, the covalently bound viral terminal protein (TP). This terminal protein stimulates the template activity over 20 fold compared to protein-free templates. To study the way in which TP exerts its function in vitro we devised a novel method to isolate and label a short origin containing fragment in which the TP was bound in a functional form. This fragment replicated very efficiently and could be used for studying the binding of other replication proteins. Employing alpha-chymotrypsin digestion we show that for enhancement of replication in vitro only a small part of TP is required.

Linker insertion mutations in the adenovirus preterminal protein that affect DNA replication activity in vivo and in vitro

Eighteen linker insertion mutants with mutations in the adenovirus precursor to terminal protein (pTP), which were originally constructed and tested in virions by Freimuth and Ginsberg (Proc. Natl. Acad. Sci. USA 83:7816-7820, 1986), were transferred to expression plasmids for assay of the various functions of the isolated pTP. Function was measured by the ability of individual pTP mutant proteins to participate in the initiation of replication from an adenovirus DNA end, by their activity in assays of DNA elongation, and by the intracellular distribution of pTP demonstrated by indirect immunofluorescence. Ten of the 11 mutants that were active in virion formation were also functional in DNA replication reactions in extracts, while 1 had reduced function. Four mutants with mutations that were lethal to virus production were also inactive in DNA replication reactions. These four mutations are probably located at sites required for the function of pTP in DNA synthesis. Three pTP mutants with mutations that were lethal or partially defective with respect to virion formation were active in reactions requiring pTP for initiation and elongation in extracts. All three of these mutant pTPs targeted normally to the nucleus, suggesting a defect after this step in replication. Since pTP has been reported to bind the nuclear matrix, these pTP mutants may have mutations that define sites necessary for binding to this structure. Several mutants with mutations that lie outside the putative nuclear targeting region were aberrantly localized, suggesting either that additional domains are important in nuclear localization or that there are alterations in protein structure that affect nuclear transport for some pTP mutants.

Mapping of the DNA linking tyrosine residue of the PRD1 terminal protein

DNA replication of PRD1, a lipid-containing phage, is initiated by a protein-priming mechanism. The terminal protein encoded by gene 8 acts as a protein primer in DNA synthesis by forming an initiation complex with the 5'-terminal nucleotide, dGMP. The linkage between the terminal protein and the 5' terminal nucleotide is a tyrosylphosphodiester bond. The PRD1 terminal protein contains 13 tyrosine residues in a total of 259 amino acids. By site-directed mutagenesis of cloned PRD1 gene 8, we replaced 12 of the 13 tyrosine residues in the terminal protein with phenylalanine and the other tyrosine residue with asparagine. Functional analysis of these mutant terminal proteins suggested that tyrosine-190 is the linking amino acid that forms a covalent bond with dGMP. Cyanogen bromide cleavage studies also implicated tyrosine-190 as the DNA-linking amino acid residue of the PRD1 terminal protein. Our results further show that tyrosine residues at both the amino-terminal and the carboxyl-terminal regions are important for the initiation complex forming activity. Predicted secondary structures for the regions around the DNA linking amino acid residues were compared in three terminal proteins (phi 29, adenovirus-2, and PRD1). While the linking amino acids serine-232 (phi 29) and serine-577 (adenovirus-2) are found in beta-turns in hydrophilic regions, the linking tyrosine-190 of the PRD1 terminal protein is found in a beta-sheet in a hydrophobic region.

Synthesis of biologically active adenovirus preterminal protein in insect cells using a baculovirus vector

A DNA fragment encoding the polyhedrin promoter of Autographa californica multiple nuclear polyhedrosis virus (AcMNPV strain) was constructed using overlapping oligodeoxyribonucleotides (oligos), which included the 5'-untranslated leader sequence of the polyhedrin-encoding gene. This DNA fragment was cloned into an intermediate transfer vector (pKX105) providing a unique BamHI site for the insertion of foreign genes. The Escherichia coli lacZ gene was first cloned at the BamHI site of pKX105 and the XhoI-KpnI fragment containing the lacZ gene was transferred to another plasmid vector (pEI) consisting of flanking AcMNPV sequences (pEI-lacZ). The E. coli beta-galactosidase that was produced in the infected insect cells using the recombinant virus constituted about 10% of the total cytoplasmic proteins. The pKX105 plasmid was also modified to give rise to pTT-lacZ which consisted of the lacZ gene under the control of the Rous sarcoma virus long terminal repeat promoter to facilitate rapid screening of the baculoviral recombinants in which the gene of interest was cloned under the control of the polyhedrin promoter. The efficiency of these transfer vectors was verified by obtaining high levels of expression of the adenovirus(Ad)-encoded preterminal protein (pTP) which is involved as a protein primer in the initiation of Ad DNA replication. The baculovirus-produced pTP was immunoprecipitable using rabbit polyclonal antibodies raised against a hydrophilic domain of pTP. The pTP protein was localized in the nucleus of the infected insect cells, and was biologically active in the in vitro Ad type 2 (Ad2) replication initiation assay.