Specific binding of the adenovirus terminal protein precursor-DNA polymerase complex to the origin of DNA replication.

Initiation of adenovirus DNA replication is dependent on a complex of the precursor of the terminal protein and the adenovirus-coded DNA polymerase (pTP-pol complex). This complex catalyzes the formation of a covalent linkage between dCMP and pTP in the presence of a functional origin of DNA replication residing in the terminal nucleotide sequence of adenovirus DNA. We have purified the pTP-pol complex of adenovirus type 5 and studied its binding to double-stranded DNA. Using DNA-cellulose chromatography it could be shown that the pTP-pol complex has a higher affinity for adenovirus DNA than for calf thymus or pBR322 DNA. From the differential binding of the pTP-pol complex to plasmids containing adenovirus terminal sequences with different deletions, it has been concluded that a sequence of 14 nucleotide pairs at positions 9-22 plays a crucial role in the binding of pTP-pol to adenovirus DNA. This region is conserved in the DNA's of all human adenovirus serotypes and is obviously an important structural element of the adenovirus origin of DNA replication. Comparative binding studies with adenovirus DNA polymerase and pTP-pol indicated that pTP is responsible for the binding. The nature of the binding of pTP-pol to the conserved sequence will be discussed.

Immunological characterization of the role of adenovirus terminal protein in viral DNA replication.

The function of the adenovirus-coded terminal protein and its precursor in viral DNA replication was studied by raising an antiserum against the adenovirus type 5 (Ad5) terminal protein isolated from virions. This antiserum reacted with both the terminal protein and its precursor as measured by a radioimmunoassay. In an in vitro DNA replication system employing nuclear extracts the addition of antiserum inhibits replication when a DNA-terminal protein complex from adenovirions is used as template. The replication of a 3.8% terminal fragment of the Ad2 genome with a protein-free origin (derived from the plasmid XD-7) is also inhibited by the antiserum. This observation confirms a role of the terminal protein precursor in DNA replication. The antiserum completely inhibited the formation of a covalent complex between the precursor terminal protein and dCMP, which is essential for initiation. A function of the terminal protein in the elongation reaction was shown by the inhibitory effect of antiserum on DNA chain elongation in isolated nuclei from Ad5-infected cells. Also in the in vitro DNA replication system employing nuclear extracts the elongation reaction is strongly reduced by addition of the antiserum. These results indicate that the terminal protein and/or its precursor are not only involved in initiation of DNA replication but also in DNA chain elongation.

Temperature-sensitive initiation and elongation of adenovirus DNA replication in vitro with nuclear extracts from H5ts36-, H5ts149-, and H5ts125-infected HeLa cells.

Adenovirus DNA replication was studied in vitro in nuclear extracts prepared from HeLa cells infected at the permissive temperature with H5ts125, H5ts36, or H5ts149, three DNA-negative mutants belonging to two different complementation groups. At the restrictive temperature, H5ts125 extracts, containing a thermolabile 72-kilodalton DNA-binding protein, enable the formation of an initiation complex between the 82-kilodalton terminal protein precursor (pTP) and dCTP, but further elongation of this complex is inhibited. Wild-type DNA-binding protein or a 47-kilodalton chymotryptic DNA-binding fragment can complement the mutant protein in the elongation reaction. No difference in heat inactivation was observed between wild-type extracts and H5ts36 or H5ts149 extracts when the replication of terminal XbaI fragments of adenovirus type 5 DNA-terminal protein complex was studied. In contrast, the formation of a pTP-dCMP initiation complex, as well as the partial elongation reaction up to nucleotide 26, were consistently more temperature sensitive in mutant extracts. The results suggest that the H5ts36/H5ts149 gene product is required for initiation of adenovirus type 5 DNA replication and that the 72-kilodalton DNA-binding protein functions early in elongation.

Replication of origin containing adenovirus DNA fragments that do not carry the terminal protein.

Nuclear extracts from adenovirus type 5 (Ad5) infected HeLa cells were used to study the template requirements for adenovirus DNA replication in vitro. When XbaI digested Ad5 DNA, containing the parental terminal protein (TP), was used as a template preferential synthesis of the terminal fragments was observed. The newly synthesized DNA was covalently bound to the 82 kD preterminal protein (pTP). Plasmid DNAs containing the Ad2 origin sequence or the Ad12 origin sequence with small deletions were analyzed for their capacity to support pTP-primed DNA replication. Circular plasmid DNAs were inactive. When plasmids were linearized to expose the adenovirus origin, both Ad2 and Ad12 TP-free fragments could support initiation and elongation similarly as Ad5 DNA-TP, although with lower efficiency. These observations indicate that the parental terminal protein is dispensable for initiation in vitro. The presence of 29 nucleotides ahead of the molecular end or a deletion of 14 base pairs extending into the conserved sequence (9-22) destroyed the template activity. DNA with a large deletion within the first 8 base pairs could still support replication while a small deletion could not. The results suggest that only G residues at a distance of 4-8 nucleotides from the start of the conserved sequence can be used as template during initiation of DNA replication.

Transfer properties of the bovine brain phospholipid transfer protein. Specificity towards phosphatidylcholine analogs and the inhibitory effect of sphingomyelin.

A coupled transport of phosphatidylinositol from the monolayer to phosphatidylcholine vesicles, and a phosphatidylcholine transport in the reverse direction in the presence of bovine brain transfer protein is demonstrated. No significant amounts of protein accumulate at the interface during the transfer reaction. The transfer protein from bovine brain shows a lower specificity for phosphatidylcholine than does the transfer protein from bovine liver. Relative to egg phosphatidylcholine a low transfer rate is found for derivatives with a chain length of 14 carbon atoms and a distance between phosphorus and nitrogen of 6 carbon atoms. The gel state of phosphatidylcholine does not reduce the transfer reaction as catalyzed by the bovine brain protein. The transfer of phosphatidylinositol is inhibited by sphingomyelin. The presence of 200 mM K+ or 1mM Ca2+ does not affect the transfer activity of the bovine brain protein. Divalent ions at concentrations higher than 5 mM cause a fusion of vesicles with monolayers. The pH optimum of the phosphatidylinositol transfer reaction is 8.