Functional characterization of thermolabile DNA-binding proteins that affect adenovirus DNA replication.

The human adenovirus type 2 (Ad2) mutant Ad2ts111 has previously been shown to contain two mutations which result in a complex phenotype. Ad2ts111 contains a single base change in the early region 1B (E1B) 19,000-molecular-weight (19K) coding region which yields a cyt deg phenotype and another defect which maps to the E2A 72K DNA-binding protein (DBP) coding region that causes a temperature-sensitive DNA replication phenotype. Here we report that the defect in the Ad2ts111 DBP is due to a single G----T transversion that results in a substitution of valine for glycine at amino acid 280. A temperature-independent revertant, Ad2ts111R10, was isolated, which reverts back to glycine at amino acid 280 yet retains the cyt and deg phenotypes caused by the 19K mutation. We physically separated the two mutations of Ad2ts111 by constructing a recombinant virus, Ad2ts111A, which contained a wild-type Ad2 E1B 19K gene and the gly----val mutation in the 72K gene. Ad2ts111A was cyt+ deg+, yet it was still defective for DNA replication at the nonpermissive temperature. The Ad2ts111 DBP mutation is located only two amino acids away from the site of the mutation in Ad2+ND1ts23, a previously sequenced DBP mutant. Biochemical studies of purified Ad2+ND1ts23 DBP showed that this protein was defective for elongation but not initiation of replication in a cell-free replication system consisting of purified Ad polymerase, terminal protein precursor, and nuclear factor I. Ad2+ND1ts23 DBP bound less tightly to single-strand DNA than did Ad2 DBP, as shown by salt gradient elution of purified DBPs from denatured DNA cellulose columns. This decreased binding to DNA was probably due to local conformational changes in the protein at a site that is critical for DNA binding rather than to global changes in protein structure, since both the Ad2+ND1ts23 and Ad2 DBPs showed identical cleavage patterns by the protease thermolysin at various temperatures.     

Purification and molecular characterization of adenovirus type 2 DNA-binding protein.

An adenovirus type 2 (Ad2) DNA-binding protein was purified by sequential DNA-cellulose, Sephadex G-200, and DEAE-Sephadex chromatography, with a yield of 120 mug of binding protein (95 to 99% homogeneity) starting with 2 X 10(9) infected cells. By omitting the Sephadex G-200 step, 400 to 600 mug of 95% pure binding protein was obtained. To obtain high yields of highly purified binding protein, it was necessary to include deoxycholate and Nonidet P-40 at selected stages during the preparation. The highly purified binding protein appeared to have retained its native stage as indicated by: (i) binding to single-stranded but not native Ad2 DNA, (ii) almost complete precipitation by immunoglobulin G from hamsters immunized by extracts of tumors induced by Ad2-simian virus 40 hybrid viruses, and (iii) identical sedimentation coefficient with binding protein obtained from DNA-cellulose chromatography only. Zonal centrifugation in sucrose gradients and gel filtration revealed that purified binding protein has a sedimentation coefficient of 3.4S and a Stokes radius of 5.2 nm. Based on these two values, a molecular weight of 73,000 was calculated, in agreement with the estimate from sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A frictional ratio of 1.88 was calculated, suggesting that the Ad2 DNA-binding protein does not have a typical globular protein structure.     

The application of high-performance liquid chromatography for the resolution of proteins encoded by the human adenovirus type 2 cell transformation region

The human adenovirus 2 (Ad2) transformation genes are located in early region E1a (map position (mp) 1.3–4.5) and E1b (mp 4.6–11.2) on the linear duplex Ad2 DNA genome of M_r 23 × 10⁶ (viral DNA is divided into 100 map units). E1b codes for three major proteins of apparent molecular weights 53,000 (53K), 19K, and 20K; smaller quantities of 21K, 22K, and 23K proteins that are related to 53K are also synthesized in Ad2-infected cells. Because the resolution and purification of these Ad2 candidate transformation proteins proved very difficult by conventional protein purification methods, the applicability of high-performance liquid chromatography (HPLC) methodology was examined. Starting with a crude cytoplasmic S100 fraction of Ad2-infected human cells, the resolution of the Ad2 E1b-coded 19K, 20K, 21K, 22K, and 23K proteins by reverse-phase HPLC using a C₈ column and a linear 0–60% 1-propanol gradient in 0.5 m pyridine formate was achieved, E1b proteins purified under these conditions retained their immunological reactivity. By anion-exchange HPLC using a linear 10 mm to 1 m NaCl gradient in 10 mm 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid buffer, pH 7.6, the same five Ad2 E1b-coded 19K–23K proteins were separated, with improved resolution of the 19K protein. Based on these findings, protocols for the extensive purification of the E1b-19K and E1b-20K proteins have been developed. These results illustrate the potential of HPLC methodology for the rapid purification of biologically interesting proteins from complex cellular mixtures of proteins.     

Identification of adenovirus 12-encoded E1A tumor antigens synthesized in infected and transformed mammalian cells and in Escherichia coli

A 16-amino acid peptide, H2N-Arg-Glu-Gln-Thr-Val-Pro-Val-Asp-Leu-Ser-Val-Lys-Arg-Pro-Arg-Cys-COOH (peptide 204), targeted to the common C-terminus of human adenovirus 12 (Ad12) tumor antigens encoded by the E1A 13S mRNA and 12S mRNA, has been synthesized. Antibody prepared in rabbits against peptide 204 immunoprecipitated two proteins of apparent Mr 47,000 and 45,000 from extracts of [35S]methionine-labeled Ad12-early infected KB cells and a 47,000 protein from extracts of the Ad12-transformed hamster cell line, HE C19. Immunoprecipitation analysis of infected and transformed cells labeled with 32Pi showed that both major Ad12 E1A T antigens are phosphoproteins. Immunofluorescence microscopy of Ad12-early infected KB cells with antipeptide antibody showed the site of E1A protein concentration to be predominantly nuclear. E1A proteins were detected by immunofluorescence at 4 to 6 h postinfection and continued to increase until at least 18 h postinfection. Antipeptide 204 antibody was used to analyze the proteins synthesized in Escherichia coli cells transformed by plasmids containing cDNA copies of the Ad12 E1A 13S mRNA or 12S mRNA under the control of the tac promoter (D. Kimelman, L. A. Lucher, M. Green, K. H. Brackmann, J. S. Symington, and M. Ptashne, Proc. Natl. Acad. Sci. U.S.A., in press). A major protein of ca. 47,000 was immunoprecipitated from extracts of each transformed E. coli cell clone. Two-dimensional gel electrophoretic analysis of immunoprecipitates revealed that the T antigens synthesized in infected KB cells, transformed hamster cells, and transformed E. coli cells possess very similar molecular weights and acidic isoelectric points of 5.2 to 5.4.     

Simian virus 40 tumor-specific proteins: subcellular distribution and metabolic stability in HeLa cells infected with nondefective adenovirus type 2-simian virus 40 hybrid viruses.

HeLa cells infected with adenovirus type 2 (Ad2)-simian virus 40 (SV40) hybrid viruses produce several SV40-specific proteins. These include the previously reported 28,000-dalton protein of Ad2+ND1, and 42,000- and 56,000-dalton proteins of Ad2+ND2, the 56,000-dalton protein of Ad2+ND4, and the 42,000-dalton protein of Ad2+ND5. In this report, we extend the list of SV40-specific proteins induced by Ad2+ND4 to include proteins of apparent molecular weights of 28,000 42,000, 60,000, 64,000, 72,000, 74,000, and a doublet of 95,000. Cell fractionation studies demonstrate that the SV40-specific proteins are detectable in the nuclear, cytoplasmic, and plasma membrane fractions. By pulse-chase and cell fractionation experiments, three classes of SV40-specific proteins can be distinguished with regard to metabolic stability: (i) unstable in the cytoplasmic but stable in the nuclear and plasma membrane fractions; (ii) stable in the nuclear, cytoplasmic, and plasma membrane fractions; and (iii) unstable in all subcellular fractions. Immunoprecipitation of infected cell extracts demonstrates that most of the above proteins share antigenic determinants with proteins expressed in hamsters bearing SV40-induced tumors. Only the 42,000-dalton protein of Ad2+ND5 is not immunoprecipitable.     

Characterization of Empty adenovirus particles assembled in the absence of a functional adenovirus IVa2 protein

The molecular mechanism for packaging of the adenovirus (Ad) genome into the capsid is likely similar to that of DNA bacteriophages and herpesviruses-the insertion of viral DNA through a portal structure into a preformed prohead driven by an ATP-hydrolyzing molecular machine. It is speculated that the IVa2 protein of adenovirus is the ATPase providing the power stroke of the packaging machinery. Purified IVa2 binds ATP in vitro and, along with a second Ad protein, the L4 22-kilodalton protein (L4-22K), binds specifically to sequences in the Ad genome that are essential for packaging. The efficiency of binding of these proteins in vitro was correlated with the efficiency of packaging in vivo. By utilizing a virus unable to express IVa2, pm8002, it was reported that IVa2 plays a role in assembly of the empty virion. We wanted to address the question of whether the ATP binding, and hence the putative ATPase activity, of IVa2 was required for its role in virus assembly. Our results show that ATPase activity was not required for the assembly of empty virus particles. In addition, we present evidence that particles were assembled in the absence of IVa2 by using two viruses null for IVa2-a deletion mutant virus, ΔIVa2, and the previously described mutant virus, pm8002. Empty virus particles produced by these IVa2 mutant viruses did not contain detectable viral DNA. We conclude that the major role of IVa2 is in viral DNA packaging. A characterization of the empty particles obtained from the IVa2 mutant viruses compared to wild-type empty particles is presented.     

Adenovirus early region 1B 58,000-dalton tumor antigen is physically associated with an early region 4 25,000-dalton protein in productively infected cells.

In soluble protein extracts obtained from adenovirus productively infected cells, monoclonal antibodies directed against the early region 1B 58,000-dalton (E1B-58K) protein immunoprecipitated, in addition to this protein, a polypeptide of 25,000 molecular weight. An analysis of tryptic peptides derived from this 25K protein demonstrated that it was unrelated to the E1B-58K protein. The tryptic peptide maps of the 25K protein produced in adenovirus 5 (Ad5)-infected HeLa cells and BHK cells were identical, whereas Ad3-infected HeLa cells produced a different 25K protein. The viral origin of this 25K protein was confirmed by an amino acid sequence determination of five methionine residues in two Ad2 tryptic peptides derived from the 25K protein. The positions of these methionine residues in the 25K protein were compared with the nucleotide sequence of Ad2 and uniquely mapped the gene for this protein to early region 4, subregion 6 of the viral genome. A mutant of Ad5 was obtained (Ad5 dl342) which failed to produce detectable levels of the E1B-58K protein. In HeLa cells infected with this mutant, monoclonal antibodies directed against the E1B-58K protein failed to detect the associated 25K protein. In 293 cells infected with Ad5 dl342, which contain an E1B-58K protein encoded by the integrated adenovirus genome, the mutant produced an E4-25K protein which associated with the E1B-58K protein derived from the integrated genome. Extracts of labeled Ad5 dl342-infected HeLa cells (E1B-58K-) were mixed in vitro with extracts of unlabeled Ad5 wild type-infected HeLa cells or 293 cells (E1B-58K+). When the mixed extracts were incubated with the E1B-58K monoclonal antibody, a labeled E4-25K protein was coimmunoprecipitated. When extracts of Ad5 dl342-infected HeLa cells and uninfected HeLa cells (both E1B-58K-) were mixed, the E1B-58K monoclonal antibody failed to immunoselect the E4-25K protein. These data provide evidence that the E1B-58K antigen is physically associated with an E4-25K protein in productively infected cells. This is the same E1B-58K protein that was previously shown to be associated with the cellular p53 antigen in adenovirus-transformed cells.     

The lef-3 gene of Autographa californica nuclear polyhedrosis virus encodes a single-stranded DNA-binding protein.

The Autographa californica nuclear polyhedrosis virus (AcNPV) replicates in the nuclei of infected cells and encodes several proteins required for viral DNA replication. As a first step in the functional characterization of viral replication proteins, we purified a single-stranded DNA-binding protein (SSB) from AcNPV-infected insect cells. Nuclear extracts were chromatographed on single-stranded DNA agarose columns. An abundant protein with an apparent molecular weight of 43,000 was eluted from the columns at 0.9 to 1.0 M NaCl. This protein was not evident in extracts prepared from control cells, suggesting that the SSB was encoded by the virus. SSB bound to single-stranded DNA in solution, and binding was nonspecific with respect to base sequence, as single-stranded vector DNA competed as efficiently as single-stranded DNA containing the AcNPV origin of DNA replication. Competition binding experiments indicated that SSB showed a preference for single-stranded DNA over double-stranded DNA. To determine whether SSB was encoded by the lef-3 gene of AcNPV, the lef-3 open reading frame was cloned under the control of the bacteriophage T7 promoter. Immunochemical analyses indicated that LEF-3 produced in bacteria or in rabbit reticulocyte lysates specifically reacted with antiserum produced by immunization with purified SSB. Immunoblot analyses of infected cell extracts revealed that SSB/LEF-3 was detected by 4 h postinfection and accumulated through 48 h postinfection.     

Mutations in the gene encoding the adenovirus early region 1B 19,000-molecular-weight tumor antigen cause the degradation of chromosomal DNA

The adenovirus mutant Ad2ts111 has been previously shown to contain a mutation in the early region 2A gene encoding the single-stranded-DNA-binding protein that results in thermolabile replication of virus DNA and a mutation in early region 1 that causes degradation of intracellular DNA. A recombinant virus, Ad2cyt106, has been constructed which contains the Ad2ts111 early region 1 mutation and the wild-type early region 2A gene from adenovirus 5. This virus, like its parent Ad2ts111, has two temperature-independent phenotypes; first, it has the ability to cause an enhanced and unusual cytopathic effect on the host cell (cytocidal [cyt] phenotype) and second, it induces degradation of cell DNA (DNA degradation [deg] phenotype). The mutation responsible for these phenotypes is a single point mutation in the gene encoding the adenovirus early region 1B (E1B) 19,000-molecular-weight (19K) tumor antigen. This mutation causes a change from a serine to an asparagine in the 20th amino acid from the amino terminus of the protein. Three other mutants that affect the E1B 19K protein function have been examined. The mutants Ad2lp5 and Ad5dl337 have both the cytocidal and DNA degradation phenotypes (cyt deg), whereas Ad2lp3 has only the cytocidal phenotype and does not induce degradation of cell DNA (cyt deg+). Thus, the DNA degradation is not caused by the altered cell morphology. Furthermore, the mutant Ad5dl337 does not make any detectable E1B 19K protein product, suggesting that the absence of E1B 19K protein function is responsible for the mutant phenotypes. A fully functional E1B 19K protein is not absolutely required for lytic growth of adenovirus 2 in HeLa cells, and its involvement in transformation of nonpermissive cells to morphological variants is discussed.     

Purification and characterization of an early glycoprotein from adenovirus type 2-infected cells.

An adenovirus type 2 early glycoprotein with an apparent molecular weight of 19,000 (E19K) in sodium dodecyl sulfate-polyacrylamide gels has been extensively purified. Purification involved detergent solubilization of membrane fractions from infected cells, followed by affinity chromatography on a lectin column and DEAE-Sephadex chromatography. The purified material contained three polypeptides (E40K, E19K, E17.5K), with approximately 90% of the material in the E19K moiety. All three polypeptides yielded identical tryptic peptide maps. The E19K polypeptide contained glucosamine as revealed by [3H]glucosamine labeling of infected cells and amino acid analysis of the purified protein. Immunoprecipitation with a monospecific antiserum showed that the E19K polypeptide started to be synthesized at 2 h, with a maximal rate at 4 h after infection. It was also synthesized at a low rate late in the infectious cycle (12 to 24 h postinfection). Immunoprecipitation from three adenovirus type 2-transformed hamster embryo cell lines and two adenovirus type 2-transformed rat cell lines revealed that one of the hamster cell lines (ad2HE4) and one of the rat cell lines (A2T2C4) expressed this protein.     

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.     

Association of adenovirus type 2 early proteins with a soluble complex that synthesizes adenovirus DNA in vitro

A soluble Ad2 DNA synthesizing complex was prepared from Ad2-infected KB cell nuclei and purified by exclusion chromatography on a BioGel A-50m column. The purified complex was able to synthesize DNA from all regions of the virus genome, as indicated by $\text{Eco}$RI restriction endonuclease analysis of $\text{in vitro}$ labeled DNA. Experiments were performed to identify Ad2-induced early polypeptides present in the complex. Ad2-infected and mock-infected cells were labeled with [³⁵S]methionine 7–10 h postinfection, then incubated for 8 h to allow the ³⁵S-labeled early polypeptides to become associated with the complex. The polypeptides in the purified complex and each of the cell fractions were identified by sodium dodecyl sulfate polyacrylamide gel electrophoresis and autoradiography. The major components of the purified complex were the 73K DNA binding phosphoprotein and 11K, two adenovirus 2-induced early polypeptides. The 11K has a preferred nuclear location. Small quantities of other Ad2-induced early proteins, 21K, 15K, and possibly 8.3K were also associated with the complex.     

Structural basis for competitive inhibition of eIF4G-Mnk1 interaction by the adenovirus 100-kilodalton protein

Translation of most cellular mRNAs involves cap binding by the translation initiation complex. Among this complex of proteins are cap-binding protein eIF4E and the eIF4E kinase Mnk1. Cap-dependent mRNA translation generally correlates with Mnk1 phosphorylation of eIF4E when both are bound to eIF4G. During the late phase of adenovirus (Ad) infection translation of cellular mRNA is inhibited, which correlates with displacement of Mnk1 from eIF4G by the viral 100-kDa (100K) protein and dephosphorylation of eIF4E. Here we describe the molecular mechanism for 100K protein displacement of Mnk1 from eIF4G and elucidate a structural basis for eIF4G interaction with Mnk1 and 100K proteins and Ad inhibition of cellular protein synthesis. The eIF4G-binding site is located in an N-terminal 66-amino-acid peptide of 100K which is sufficient to bind eIF4G, displace Mnk1, block eIF4E phosphorylation, and inhibit eIF4F (cap)-dependent cellular mRNA translation. Ad 100K and Mnk1 proteins possess a common eIF4G-binding motif, but 100K protein binds more strongly to eIF4G than does Mnk1. Unlike Mnk1, for which binding to eIF4G is RNA dependent, competitive binding by 100K protein is RNA independent. These data support a model whereby 100K protein blocks cellular protein synthesis by coopting eIF4G and cap-initiation complexes regardless of their association with mRNA and displacing or blocking binding by Mnk1, which occurs only on preassembled complexes, resulting in dephosphorylation of eIF4E.