Characterization of the pH 4.0 endonuclease from adenovirus-type-2-infected KB cells.

The properties of the pH 4.0 endonuclease from adenovirus-type-2-infected KB cells were determined. The enzyme has a molecular weight of approximately 40000. Its pH optimum is at pH 4.0, it is not inhibited by ethylenediaminetetraacetate (EDTA), and it is active at temperatures up to 60 degree C. The enzyme cleaves adenovirus DNA in a stepwise manner. The limit digestion product has a molecular weight of 120000-200000. There is evidence that the cleavage reaction proceeds via an initial single-strand nick. Under the conditions tested the endonuclease did not seem to reveal a high degree of specificity as to the recognition of cleavage sites, or else the sites recognized occurred very frequently.     

Three new virus-specific low molecular RNAs in adenovirus type 2 infected KB cells.

With the use of alkyl agarose columns which separate proteins according to their lipophilic affinities, a marked correlation has been uncovered between this parameter of proteins and their degradation rates $\text{in}$$\text{vivo}$. The possible relationship between these observations and analogous ones with other properties of proteins and their implications in regard to the mechanism of the turnover process are discussed.     

Transcription of the genome of adenovirus type 12. Viral mRNA in productively infected KB cells.

In human KB cells productively infected with adenovirus type 12, viral DNA replication starts between 12 and 14h postinfection. Virus-specific, polysome-associated mRNA was investigated early (6-8h) and late (26-28h) after infection. Most of the viral mRNA was polyadenylated and accounted for 0.46% and 24.1% of the mRNA synthesized early and late postinfection, respectively. The viral-specific mRNA isolated both early and late after infection falls into several distinct size-classes, ranging in molecular weights between 0.3X10(6) and 1.5X10(6) for the early RNA and between 0.6X10(6) and 2.3X10(6) for the RNA synthesized late in the infection.     

Purification of an endonuclease from adenovirus-infected KB cells.

This report describes the purification of an endonuclease from extracts of adenovirus-type-2-infected KB cells. Endonuclease activity can also be detected in extracts of uninfected KB cells and the enzyme activities from extracts of uninfected and adenovirus-infected cells are very similar, if not identical. The enzyme has its maximal activity at pH 4.0. The enzyme found in uninfected and adenovirus-infectedcells is, however, strikingly different from an endonuclease isolated from calf serum. Hence, the endonuclease described is probably not a contaminant derived from the medium in which the KB cells were propagated. The endonuclease in crude extracts from uninfected or adenovirus-infected KB cells can be activated or its activity enhanced by treatment of the extracts with proteolytic enzymes, like pronase or trypsin. Evidence has been presented suggesting that this activation is due to proteolytic cleavage of an inhibitor present in crude extracts of uninfected and adenovirus-type-2-infected KB cells. A second endonuclease has been found in extracts of infected and uninfected cells with optimal activity at pH 7.2 and this endonuclease can be separated from the one with a pH optimum at 4.0.     

Degradation of intracellular DNA in KB cells infected with cyt mutants of human adenovirus type 12.

A group of mutants (cyt mutants) with much reduced oncogenicity was isolated from the highly oncogenic human adenovirus type 12 (Takemori et al., Virology 36: 575-586, 1968). These mutants induce extensive cellular destruction during lytic infection of human cells and produce low yields of virions. We report here that human KB cells infected with cyt mutants synthesized a reduced amount of viral DNA as compared with cells infected with the parental virus. Furthermore, the newly synthesized viral and cellular DNAs were extensively degraded in mutant-infected cells. Viral DNA was first synthesized as complete genome size, and most of it was degraded to subgenomic size within 6 h after synthesis. This virus-induced DNA degradation function, as well as the low yield of virions, was prevented by co-infection with the parental virus.     

Messenger ribonucleoprotein complexes in human KB cells infected with adenovirus type 5 contain tightly bound viral-coded '100K' proteins.

Late after infection of KB cells with adenovirus 5 an extra protein becomes associated with messenger ribonucleoprotein particles present in the polysomes. This protein has a molecular weight of 100000 and is identical to the virus coded '100K' protein found previously. The extra protein is firmly attached to the messenger ribonucleoprotein complexes. Its binding resists exposure to high salt concentrations as used in puromycin/high-salt dissociation and equilibrium centrifugation in Cs2SO4 gradients. In this respect it resembles the binding of two other proteins of Mr 74000 and 48000 which are commonly found in messenger ribonucleoprotein particles of various eukaryotic cells. The identity between the messenger ribonucleoprotein protein of Mr 100000 and the "100K' protein present in the soluble part of the cytoplasm was established by sodium dodecylsulphate/polyacrylamide gel electrophoresis, isoelectric focusing and peptide mapping after limited proteolysis with Staphylococcus aureus protease.     

Replication of adenovirus type 4 DNA by a purified fraction from infected cells.

An extract from Adenovirus type 4 infected HeLa cells was fractionated by ion-exchange and DNA affinity chromatography. One fraction, which bound tightly to single stranded DNA, contained predominantly a protein of apparent molecular weight 65,000 and three less abundant proteins. Immunological cross-reactivity with adenovirus type 2 proteins confirmed the presence of preterminal protein and indicated that the abundant species was the virus coded DNA binding protein. This fraction contained an aphidicolin resistant DNA polymerase activity and in the presence of a linearised plasmid containing the adenovirus type 4 origin of DNA replication efficient transfer of dCMP onto preterminal protein, indicative of initiation, was observed. Furthermore, addition of all four deoxyribonucleotide triphosphates and an ATP regenerating system resulted in the elongation of initiated molecules to generate plasmid molecules covalently attached to preterminal protein. Adenovirus type 4 DNA binding protein was extensively purified from crude adenovirus-4 infected HeLa extract by immunoaffinity chromatography using a monoclonal antibody raised against adenovirus type 2 DNA binding protein. A low level of initiation of DNA replication was detected in the fraction depleted of DNA binding protein but activity was restored by addition of purified DNA binding protein. DNA binding protein therefore plays an important role in the initiation of Ad4 DNA replication.     

Immunofluorescence study of the adenovirus type 2 single-stranded DNA binding protein in infected and transformed cells.

High-titer monospecific antiserum against highly purified adenovirus 2 (Ad2) single-stranded DNA binding protein (DBP) was used to study, by indirect immunofluorescence (IF), the synthesis of DBP in Ad2-infected human cells and adenovirus-transformed rat, hamster, and human cell lines. In infected cells the synthesis of DBP was first detected in the cytoplasm at 2 to 4 h postinfection and reached a maximum intensity at 6 h postinfection. At this time DBP began to accumulate in the nucleus, where it reached maximum intensity at about 14 h postinfection. The cytoplasmic IF was diffuse, whereas nuclear IF appeared as dots that coalesced into large globules as infection progressed. In cells treated with 1-beta-d-arabinofuranosylcytosine to inhibit viral DNA synthesis, strong nuclear IF was observed in the form of dots, but the large fluorescent globules were not observed. The Ad2 (oncogenic group C) anti-DBP serum reacted very strongly by IF with Ad5 (group C)-infected, to a lesser extent with Ad7 and Ad11 (group B)-infected, and weakly with Ad12 and Ad18 (group A)-infected KB cells (treated with 1-beta-d-arabinofuranosylcytosine). These results may indicate that Ad2 DBP is closely related immunologically to DBPs induced early after infection by adenovirus serotypes in oncogenic group C, moderately related to DBPs of serotypes in oncogenic group B, and perhaps distantly related to DBPs of serotypes in oncogenic group A. The following adenovirus-transformed cell lines were examined for DBP synthesis by IF with the Ad2 anti-DBP serum: six rat cell lines (T2C4, F17, 8662, 8638, 8617, and F161) transformed by Ad2 virus, three hamster cell lines transformed by Ad2 virus (Ad2HT1) and Ad2-simian virus 40 hybrid virus (ND1HK1 and ND4HK4), and one rat (5RK) and one human (293-31) cell line transformed by transfection with Ad5 DNA. T2C4 and 8662 appeared weakly positive, whereas Ad2HT1 and ND4HK1 were strongly positive. The other transformed cell lines did not produce DBP detectable by IF. Thus, some but not all transformed cell lines produce DBP, which indicates that DBP is not required for maintenance of cell transformation and that transformed cells can express "nontransforming" viral genes as protein.     

In vitro cleavage specificity of the adenovirus type 2 proteinase

Two in vitro proteinase assay systems were developed and used to study the peptide bond specificity and substrate specificity of the adenovirus endoproteinase. Five adenovirus precursor proteins (PVI, PVII, PVIII, 87K, 11K), all found in the virion of the ts1 mutant grown at the nonpermissive temperature, were digested by the proteinase. All, except 11K, were cleaved to their mature counterparts. Some of the proteins, particularly the 87K terminal protein, were processed via cleavage intermediates similar to those found in vivo. The data suggest that the proteinase specifically hydrolyses Gly-Ala bonds. The high specificity for the natural substrates and the failure to cleave foreign proteins suggest that cleavage activity is determined not only by primary sequence but also by other physical features of the substrate. Enzyme activity was inhibited by diisopropylfluorophosphate, showing that it is a serine proteinase.     

In vitro translation of adenovirus type 12-specific mRNA isolated from infected and transformed cells.

The early and late gene products of human adenovirus type 12 (Ad12), as well as the viral proteins synthesized in an Ad12-transformed cell line, were identified by translation of viral mRNA in an in vitro protein-synthesizing system. Cytoplasmic RNA was isolated from permissive KB or nonpermissive BHK cells infected with Ad12 and from Ad12-transformed HA12/7 cells. Virus-specific RNA was selected by hybridization to Ad12 DNA covalently bound to cellulose. Viral RNA was then translated in a fractionated rabbit reticulocyte cell-free system or in wheat germ S-30 extracts. The proteins synthesized were characterized by immunoprecipitation and subsequent electrophoresis on sodium dodecyl sulfate-polyacrylamide gels. RNA prepared from KB cells late after infection with Ad12 elicited the synthesis of most of the structural polypeptides of the virion and at least two presumably nonstructural Ad12 proteins. When viral RNA isolated early after infection of KB cells with Ad12 was translated in vitro, 10 polypeptides were observed: E-68K, E-50K, E-42K, E-39K, E-34K, E-21K, E-19K, E-13K, E-12K, and E-10K. Ad12-specific RNA was also isolated from the Ad12-transformed hamster cell line HA12/7, which contains several copies of the Ad12 genome integrated in the host genome. The RNA codes for at least seven polypeptides with molecular weights very similar to those of the early viral proteins.     

A new species of virus-coded low molecular weight RNA from cells infected with adenovirus type 2

A virus-coded low molecular weight RNA (5.2S), which migrates slightly faster on polyacrylamide gels than the well characterized adenovirus-specific 5.5S RNA, has been isolated from cells infected with adenovirus type 2. Hybridization-competition experiments and RNA fingerprints indicate that the two virus-associated (VA) RNAs differ in their primary structures. The gene for 5.2S RNA is located to the right of the gene for 5.5S RNA, on the I strand of a DNA segment which extends between positions 30.3 and 32.2 on the map of adenovirus type 2 DNA.Both 5.5S and 5.2S RNA can be detected early after infection and also in the presence of cytosine-arabinoside or cycloheximide. After the onset of viral DNA replication, the synthesis of 5.2S RNA levels off, whereas 5.5S RNA is synthesized in increasing amounts. Both 5.2S and 5.5S RNAs are synthesized in isolated nuclei by an enzyme which resembles RNA polymerase III in its sensitivity to α-amanitin. In isolated nuclei, both RNA species are labeled with β-³²P-labeled GTP, which suggests that they are initiated at separate promoter sites.     

Kinetic studies on the cleavage of adenovirus DNA by restriction endonuclease Eco RI.

The kinetics of cleavage of DNA from Adenovirus Type 1 (Ad1), Type 5 (Ad5) and Type 6 (Ad6) by restriction endonuclease EcoRI was investigated by quantitative evaluation of the fluorescence from ethidium stained DNA fragments separated on agarose gels. The apparent rate constants of cleavage at different cleavage sites have been determined and large differences in the cleavage rates of the individual sites within one type of DNA were found. From the kinetics of cleavage information on the sequence of the DNA fragments can be obtained. The order of the fragment A, B, C, D of Ad6 DNA obtained after complete cleavage by restriction endonuclease Eco RI was found to be A-D-C-B; the order of the corresponding fragments A, B, C of Ad1 and Ad5 DNA was found to be A-C-B.