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.

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.

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.

Recognition of non-B DNA structures by cellular proteins.

By utilising a gel retardation assay, cytoplasmic extracts of Hela cells have been shown to contain a number of polypeptides which bind preferentially to non-B forms of DNA. These polypeptides vary in apparent molecular weights and are present as minor components of the total extract. Similar properties were demonstrated by purified preparations of eukaryotic topoisomerase I and by a DNA binding subunit of the transcription factor NFkB. These results suggest that non-B DNA binding proteins may represent families of proteins which recognise more open forms of DNA as a cognate parameter to their cellular functions.

The DNA-binding domain of nuclear factor I is sufficient to cooperate with the adenovirus type 2 DNA-binding protein in viral DNA replication.

Recombinant baculoviruses have been constructed which express the full-length nuclear factor I (NFI) protein or a derivative of NFI that contains only the DNA-binding domain of the protein in infected insect cells. Both proteins were purified from insect cells infected with the respective baculoviruses and tested for their ability to cooperate with the adenovirus type 2 (Ad2) DNA-binding protein during virus replication. DNase I protection experiments demonstrated that the viral DNA-binding protein increased the affinity of both the full-length NFI and the DNA-binding domain of NFI for their recognition site in the Ad2 origin of DNA replication. As a consequence, the NFI-dependent increase in the efficiency of DNA replication observed upon addition of viral DNA-binding protein was the same when the full-length or DNA-binding domain derivative of NFI was added. Thus it appears that all of the activities associated with the ability of NFI to stimulate Ad2 DNA replication are located within the DNA-binding domain of the protein.

Adenovirus subviral particles and cores can support limited DNA replication.

Adenovirus type 2 cores can function effectively as templates in an in vitro replication system. Viral DNA replication assays using cores as templates do not differ in their requirements to the well characterized assays using DNA-complex templates, i.e. there is a dependence on terminal protein precursor (pTP), DNA polymerase and DNA binding protein and the assay is greatly stimulated by certain host transcription factors. The products of initiation and limited elongation are easily distinguishable and, in the system described, there is specific proteolysis of the pTP adducts as a function of the adenovirus-coded protease, present in the nuclear extracts from infected cells, or the core templates. Substitution of Mn2+ ions for Mg2+ ions in the replication assay has a dramatic effect on the nature of the replication events, in most cases resulting in the stimulation of initiation without elongation. Similar results can be achieved by utilizing subviral particles as templates, obtained by dialysis of purified adenovirus in a hypotonic buffer at pH 6.4. Restriction enzyme analysis of the replicated products confirmed that DNA synthesis proceeds from the adenovirus termini using both the core and subviral templates. By adding an ATP-regenerating system elongation can be further stimulated, particularly in the case of the subviral templates. Quantification of nucleotide incorporation into the appropriate restriction fragments indicates that for the subviral templates replication can proceed for at least 2000 to 3000 bases from either terminus. These results suggest that the adenovirus genome is packaged in the virion in a conformation readily available for at least the initial replication events. Such a conformation might also be appropriate for early transcription.

Phosphorylation of adenovirus DNA-binding protein.

Evidence is presented here which indicates that the adenovirus DNA-binding protein (DBP) is phosphorylated at a tyrosine residue early in infection. This was suggested by the discovery that a proportion of the label in 32P-labelled DBP was resistant to alkali, and was substantiated by acid hydrolysis of DBP immunoprecipitates and by immunoblotting with a monoclonal antibody against phosphotyrosine. Treatment of [35S]methionine-labelled DBPs with chymotrypsin produced fragments of apparent Mr 45K and 39K whereas digestion of 32P-labelled DBP resulted in fragments of 45K and 26K. Consideration of the distribution of 32P label and its alkali stability in these fragments suggested that chymotrypsin cleaved populations of DBP at different sites depending on their phosphorylation states. The conservation, in all of the seven adenovirus serotypes sequenced, of a tyrosine residue (at amino acid 195 in adenovirus type 2) together with its surrounding residues, suggests that phosphorylation/dephosphorylation at this tyrosine residue may be important in various functions ascribed to the DBP.

Detection of Z DNA binding proteins in tissue culture cells.

A gel electrophoresis DNA binding assay to detect Z DNA binding proteins has been developed utilising [32P] labelled poly [d(G-C)] which was converted to the Z form by incubation in 100 microM Co(NH3)6Cl3. The parameters of the assay were established using a Z DNA antibody as a model system and then applied to extracts of Hela and BHK21 cells. Using an anti-Z DNA antibody conditions were established which allowed resolution of antibody-DNA complexes and free DNA in the presence of 100 microM Co(NH3)6Cl3. The inclusion of unlabelled complementary homopolymers eliminated non-specific binding to the labelled Z-DNA probe. Competition experiments demonstrated that the assay was highly specific for double stranded non-B DNA. Application of the technique to extracts of mammalian cells demonstrated that human and hamster cells contain Z-DNA binding proteins; further characterisation by a blotting technique indicated that a 56,000 molecular weight cell protein preferentially binds Z-DNA.